Search Index

What they are, uses, and future outlook Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Advancements in Semiconductor Laser Technology 11/04/26, 14:51 Last updated: Published: 23/06/24, 09:39 What they are, uses, and future outlook Lasers have revolutionised many fields starting from the telecommunications, data storage to medical diagnostics and consumer electronics. And among the semiconductor laser technologies, Edge Emitting Lasers (EEL) and Vertical Cavity Surface Emitting Lasers (VCSEL) emerged as critical components due to their unique properties and performance. These lasers generate light through the recombination of electrons and holes in a semiconductor material. EELs are known for their high power and efficiency and they are extensively used in fiber optic communications and laser printing. VCSELs on the other hand are compact and are used for applications like 3D sensing. Traditionally VCSELs have struggled to match the efficiency levels of EELs however a recent breakthrough particularly in multi junction VCSEL, has demonstrated remarkable efficiency improvements which place the VCSELs to surpass EELs in various applications. This article focuses on the basics of these laser technologies and their recent advancements. EELs are a type of laser where light is emitted from the edge of the semiconductor wafer. This design contrasts with the VCSELs which emit light perpendicular to the wafer surface. EELs are known for their high power output and efficiency which makes them particularly suitable for applications that require long-distance light transmission such as fiber optic communications, laser printing and industrial machining. EELs consist of an active region where electron hole recombination occurs to produce light. This region is sandwiched between two mirrors forming a resonant optical cavity. The emitted light travels parallel to the plane of the semiconductor layers and exits from the edge of the device. This design allows EELs to achieve high gain and power output which makes them effective for transmitting light over long distances with minimal loss. VCSELs are a type of semiconductor laser that emits light perpendicular to the surface of the semiconductor wafer unlike the EELs which emit light from the edge. VCSELs have gained popularity due to their lower threshold currents and ability to form high density arrays. VCSELs consist of an active region where electron-hole recombination occurs to produce light. This region is situated between two highly reflective mirrors which forms a vertical resonant optical cavity. The light is emitted perpendicular to the wafer surface which allows for efficient vertical emission and easy integration into arrays. Recent advancements in VCSEL technology marked a significant milestone in the field of semiconductor lasers. And in particular the development of multi junction VCSEL which led to the improvements in power conversion efficiency (PCE) of the laser. Research conducted by Yao Xiao et al. and team has demonstrated the potential of a multi junction VCSELs to achieve efficiency levels which were previously thought unattainable. This research focuses on cascading multiple active regions within a single VCSEL to enhance gain and reduce threshold current which leads to higher overall efficiency. The study employed a multi-junction design where several active regions are stacked vertically within the VCSEL. This design increases the volume of the gain region and lowers the threshold current density resulting in higher efficiency. Experimental results from the study revealed that a 15-junction VCSEL achieved a PCE of 74% at room temperature when driven by nanosecond pulses. This efficiency is the highest ever reported for VCSELs and represents a significant leap forward from previous records. Simulations conducted as part of the study indicated that a 20-junction VCSEL could potentially reach a PCE exceeding 88% at room temperature. This suggests that further optimization and refinement of the multi-junction approach could yield even greater efficiencies. The implications of this research are profound for the future of VCSEL technology. Achieving such high efficiencies places VCSELs as strong competitors to EELs, particularly in applications where energy efficiency and power density are critical. The multi junction VCSELs demonstrated in the study shows promise for a wide range of applications and future works may focus on optimising the fabrication process, reducing thermal management issues and exploring new materials to further enhance performance. Integrating these high-efficiency VCSELs into commercial products could revolutionise industries reliant on laser technology. Note: latest research shows development of photonic crystal surface-emitting lasers (PCSELs) for free-space optics, offering superior power and beam quality compared to traditional VCSELs. Written by Arun Sreeraj Related articles: The future of semi-conductor manufacturing / The search for a room-temperature superconductor / Advances in mass spectrometry Project Gallery

AI in developing different space technologies Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Artificial intelligence in space 11/04/26, 14:03 Last updated: Published: 19/11/23, 17:31 AI in developing different space technologies Artificial intelligence or AI has become an important force or a tool that drives the evolution of technologies that improve human life and helps unlock the secrets of the universe beyond the influence of our planet. In simple words, AI is something that enables a computer/ robot to mimic human intelligence and it is revolutionizing the way we explore and utilise space, enhancing everything from spacecraft navigation and autonomous decision-making to data analysis and mission planning. This article explores the profound impact of AI in the development of space related technologies. Mission planning and design Space mission planning and payload, instrument designs rely on the gathered previous mission data. However, access to all the historic mission data is only provided to individuals with a higher authority access at the space agency which requires a lot of paper works and approvals. But recently NASA came up with a solution and they named it as the “Data Acquisition Processing and Handling Network Environment” (DAPHNE) system. Daphne-AT is an AI assistant that can access millions of previous mission data including the most restricted ones and provide the scientists an insight about their mission without the need of a higher authority access or security clearance. It can also compute and analyse countless input variables to determine the most efficient routes and schedules for missions, which is crucial for long-duration missions or missions with multiple objectives. Manufacturing Manufacturing processes usually involves complex tasks that requires high precision and attention to detail when it comes to space related applications. The use of AI in spacecraft manufacturing not only accelerates production but also increases precision and reliability. AI assistants like collaborative bots (cobots) interact with the engineers and help them to make the right decisions, reduce the overall assembly process time, and also provide insights about the final product which ensures that the spacecrafts are built to the highest standards. Data processing Space missions generate vast amounts of data, from images and telemetry to instrument readings. AI algorithms are capable in sifting through this data, identifying patterns, and extracting meaningful insights. An example is the estimation of planetary wind speed which requires a combination of the satellite imagery and meteorological data. AI tools can rapidly analyse these large datasets and help scientists in understanding these planetary phenomena and easily uncover its secrets. This capability is also valuable in missions to study distant galaxies, black holes, and exoplanets. Navigation & guidance systems One of the critical applications of AI in space technology is autonomous navigation. Spacecraft traveling vast distances through the cosmos must constantly adjust their trajectories to avoid collisions with celestial bodies and maximise their fuel efficiency. Advanced AI systems can process data in real-time and autonomously adjust a spacecraft's course. This not only reduces the need for constant human intervention from the ground station but also allows for more precise and efficient missions. Astronaut health monitoring Astronauts in space face a range of health issues like bone density loss, cardiovascular issues etc. The AI systems can continuously monitor physiological data and provide an insight into the astronaut’s health condition including sleep patterns. This allows early detection of health issues and timely intervention which reduces the need for immediate communication with ground mission control, ultimately safeguard the safety of the astronauts on long-duration missions. In summary, AI is a tool that represents a transformative shift in how we explore and understand our cosmos and its secrets. One day, AI will play an even more significant role that pushes the boundaries of space and bring us closer to answering some of humanity’s most profound questions. Written by Arun Sreeraj Related articles: Astronauts in space / AI in drug discovery / Evolution of AI / Chemistry in space exploration Project Gallery

Scientia News is full of STEM blogs, articles and resources freely available across the globe for students. Browse all of our fascinating content written by students and professionals showing their passion in STEM and the other sciences. Log In Welcome to Scientia News DELIVERING INFORMATIVE CONTENT Scientia News is full of STEM blogs, articles and resources freely available across the globe for students. Browse all of our fascinating content written by students and professionals showing their passion in STEM and other sciences. We hope this platform helps you discover something that inspires your curiosity, and encourages you to learn more about important topics in STEM. Meet the Official Team NAVIGATE AND CLICK THE PHOTOS BELOW TO LEARN MORE ABOUT US! To play, press and hold the enter key. To stop, release the enter key. To play, press and hold the enter key. To stop, release the enter key. To play, press and hold the enter key. To stop, release the enter key. Latest Articles ecology Rock, paper, survival? View More chemistry Diels–Alder Reaction View More biology Addressing Health Inequalities View More chemistry Molecular blueprints: the synthesis of ibuprofen View More CONTACT CONTACT US Scientia News welcomes anyone who wants to share their ideas and write for our platform. If you are interested in realising your writing potential with us AND live in the UK; and/ or would like to give feedback: Email us at scientianewsorg@gmail.com or fill in our GET IN TOUCH form below and we'll be in contact... Follow us on our socials for the latest updates. Comment, like and share! Join our mailing list below for latest site content. You can also sign up to become a site member . SUBSCRIPTION Join our mailing list to receive alerts for new articles and other site content. Be sure to check your spam/ junk folders in case emails are sent there. Email Subscribe GET IN TOUCH First Name Last Name Email Message Send Thanks for submitting!

An extensive collection of insightful reviews on the best STEM books available. Whether you're a student looking to deepen your knowledge or something to aid your revision and research, an educator seeking great resources for your classroom, or simply a curious mind passionate about science, technology, engineering, mathematics, medicine and more, you'll find something here to inspire and inform you.  Discover Your Next Great Read Deep Dive into STEM Books Here you can explore an extensive collection of insightful reviews on the best STEM books available. Whether you're a student looking to deepen your knowledge or something to aid or complement your revision and research, an educator seeking great resources for your classroom, or simply a curious mind passionate about science, technology, engineering, mathematics, medicine and more, you'll find something here to inspire and inform you. Our Curated Selections: Intern Blues by Robert Marion, M.D. The Emperor of All Maladies by Siddhartha Mukherjee The Molecule by Dr Rick Sax and Marta New

Hydrogen fuel cells generate electricity through an electrochemical reaction between hydrogen and oxygen Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Are hydrogen cars the future of the UK? 11/04/26, 15:14 Last updated: Published: 01/01/25, 13:50 Hydrogen fuel cells generate electricity through an electrochemical reaction between hydrogen and oxygen Introduction With the London debut of the first ever hydrogen powered racing car in June 2024, the new off-road racing series, Extreme H, is set to make waves in the motorsport and sustainability industries with its first season in 2025. The first ever hydrogen powered motorsport series was announced in 2022 to replace the carbon-neutral electric racing series Extreme E, with the intention of pioneering the potential of hydrogen fuel cells and diversifying the paths of sustainable mobility. Like its predecessor, Extreme H will continue to race off-road in a spec SUV car, where engineers and machinists from competing teams optimise the SUV for the different range of terrains and topographies. The hydrogen spec SUV, fittingly called the Pioneer 25 ( Figure 1 ), is promising for the rapid advancement of hydrogen fuel research, leading to the integration of hydrogen fuel cells vehicles on local roads. In line with the upcoming ban on the sale of new petrol, diesel, and hybrid cars across the UK in 2035, as well as the UK target of reaching carbon neutral by 2050, the need for sustainable and practical transport options is growing. So far however, electric cars have proved to not be a one-size-fits-all solution. Hydrogen fuel could potentially be the key to filling this gap. EVs vs. HFCVs Working mechanisms Hydrogen Fuel Cell Vehicles (HFCVs): Hydrogen fuel cells generate electricity through an electrochemical reaction between hydrogen and oxygen. The electricity produced is used to power an electric motor, which drives the car. The only byproduct of this process is water vapour. Electric Vehicles (EVs): A motor is powered directly from a charged battery, and equally produces no harmful emissions. As a result of large investments, electric vehicles have already established a strong footing in the UK market, prompting the declining cost of batteries as well as increasing availability of EV charging points in the UK. However, for many households and commercial uses, electric vehicles are not accessible forms of transport due to key barriers including the extensive charging time (around 8 hours), the weight of batteries for large vehicles, and performance decline in cold weather due to lithium-ion batteries being highly sensitive to temperature. HFCVs directly address these problems and present a sustainable and competitive alternative. As the refuelling process is the same as petrol and diesel cars, fuel tanks can be filled in the space of a few minutes and are notably weight efficient. A heavy-duty electric vehicle on the other hand can require a battery of around 7000 kg. Advantages of HFCVs: Significantly shorter refuelling times Can achieve 300-400 miles on a full tank Maintain performance in cold weather and under heavy loads Lighter and more energy-dense than electric vehicles Disadvantages: Expensive as they’re not yet widely available Lack of refuelling infrastructure The current primary method of hydrogen production produces CO2 as a byproduct Despite the key advantages hydrogen cars offer, there are currently only 2 available models of HFC cars in the UK, including the Toyota Mirai ( Figure 2 ) and the Hyundai Nexo SUV. As a result, there are currently fewer than 20 refuelling stations available nationwide, compared to the many thousands of charging points available across the country for electric vehicles. One of the main reasons why progress in hydrogen fuel production has been so delayed is because hydrogen, despite being the most abundant element in the universe, is only available on earth in compound form and needs to be extracted using chemical processes. The true sustainability of hydrogen production There are currently two main methods to extract hydrogen from nature, including steam-methane reforming and electrolysis. Hydrogen is colour-graded by production method to indicate whether it is renewable. Green/ yellow hydrogen The cleanest process for hydrogen production is electrolysis, where a current separates hydrogen from pure water. If the current is sourced from renewable energy, it’s known as green hydrogen. If it’s connected via the grid, then it’s called yellow hydrogen. The source of electricity is particularly important because the electrolysis process is about 75% efficient, which translates to higher costs yet cleaner air. Grey/ blue hydrogen Hydrogen can also be produced by treating natural gas or methane with hot steam. During this process, the methane splits into its four hydrogen atoms while one carbon atom bonds to oxygen and enters the atmosphere as carbon dioxide. This is known as grey hydrogen. If the carbon dioxide can be captured and stored via direct air capture, it’s called blue hydrogen. About 95% of all hydrogen in Europe is produced by methane steam reforming (grey and blue hydrogen), as it is very energy efficient and uses up lots of natural gas in the process, a resource that is quickly diminishing in importance and value as more and more households switch from gas boilers to heat pumps. Two percent of the world’s carbon emissions comes from the grey hydrogen process to produce ammonia for fertiliser and for steel production. For context, this is almost the same as the entire aviation industry. For HFCVs to be a truly sustainable alternative to combustion engines, green hydrogen via electrolysis (or another clean process) needs to be more widely available and economically viable. The UK’s plans for hydrogen As part of the UK hydrogen strategy ( Figure 3 ), the UK aims to reach up to 10GW or low carbon hydrogen production by 2030 (or equivalent to the amount of gas consumed by 3 million households in the UK annually). The government has allocated £240 million to develop hydrogen production and infrastructure. This is particularly for industry uses in the production of steel and cement, and for heavy goods vehicles (HGVs). Plans were also made to extend the use of hydrogen to heat homes, starting with ‘hydrogen village trials’ in 2025, to inform how 100% hydrogen communities would work, although this has understandably been met with local opposition. With greater research, information, and development into hydrogen for domestic uses, the applications of hydrogen energy may extend from industry and transport to households. As car companies (particularly Toyota, Hyundai, and BMW) continue to develop hydrogen car makes, and further investment is made into increased refuelling infrastructure and hydrogen fuel cell research, as well as with the ban on the sale of new combustion engine cars by 2035, commercial hydrogen cars have the potential to be commonly found on UK roads by 2040. Conclusion For now, HFCVs remain in the early stages of development, however they present a promising opportunity for the UK to diversify its clean transport options, particularly in areas where EV technology faces limitations such as for heavy goods vehicles. Rather than being competitors, it is likely that EVs and HFCVs will soon coexist, with each technology serving different needs. The biggest barrier to the progress of HFCVs currently is developing a full hydrogen refuelling infrastructure, where the gas is produced and then transported to stations across the nation, which will take billions of pounds and a number of years to develop. If these initial hurdles could be overcome, HFCV technology can quickly become more practically and financially accessible. Written by Varuna Ganeshamoorthy Related articles: Electric vehicles / Nuclear fusion Project Gallery

Beyond sugarcane fields and dreamy beaches, Mauritius secures first place in mobile connectivity Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Mauritius's rise as African leader of mobile networks Last updated: 11/04/26, 15:04 Published: 05/06/25, 07:00 Beyond sugarcane fields and dreamy beaches, Mauritius secures first place in mobile connectivity Background: GSMA ranking In the bustling capital city of Port Louis, commuters check the latest news updates using mobile data on their phones. Across the busy, connecting streets, a handful of tourists video call their family back home, asking them what souvenirs they would like- also on mobile data. Apart from idyllic holiday scenes and solid sugar exports, the island nation of Mauritius has become number one in Africa for mobile connectivity- as scored by the Global System for Mobile Communications Association (GSMA). The small island is now at the forefront of telecommunication development, with the increasing rollout of 5G networks. How did this touristic country become a leader in mobile connectivity? On the 13th of August 2024, the GSMA announced its yearly index for mobile connectivity. The GSMA looks at 41 African countries and ranks them based on: internet accessibility, prices of mobile devices, relevant services and political environments. Scoring 62.7 points out of the possible 100, Mauritius took the first spot, in front of South Africa. This result also places the island country 76th in the world. Remarkably, this is the third consecutive year that Mauritius is leading in mobile connectivity in Africa. Moreover Mauritius, with a population of 1.26 million, boasts an average of 1.7 phones per person, compared to only 1.2 phones per person in the US (according to 2023 data). Connecting the island: 5G is nearly everywhere Three companies provide mobile phone networks on Mauritius island: Emtel, MTML (Chili) and state-owned My.t. At present, 5G is widely available in Mauritius, thanks to Emtel supplying it to approximately 80% of the island for both residential and commercial usage. Though Emtel is the biggest network in the country, My.t is the most popular provider currently, and it also offers 5G to its users. A closer look at 4G and 5G 3G (and 3G High-Speed Packet Access, HSPA), 4G (Long Term Evolution, LTE) and 5G are wireless mobile networks, where the ‘G’ in these networks means ‘generation’ and indicates the strength of the signal on the mobile device. Hence, each mobile network is an improvement since the last generation of network. These mobile networks aim for high quality, reliable communication, and are based on radio signals. Each generation has evolved to achieve this. Table 1 compares the differences between all of these networks. The original 1G network from 1979 used analogue radio signals, while subsequent network generations use digital radio signals. Table 1: A comparison of 2G, 3G, 4G and 5G mobile networks 2G 3G HSPA+ 4G LTE 5G Speed 64Kbps 8Mbps 50Mbps 10Gbps Bandwidth 30- 200 kHz 15- 20 MHz 100 MHz 30- 300 GHz Features Better quality video calls than before Can send and receive larger emails Higher speeds and capacities Much faster speeds and capacities; high resolution video streaming SMS and MMS Larger capacities Low cost per bit Low latency Interactive multimedia, voice, video Allows remote control of operations e.g. vehicles, robots, medical procedures It is evident from Table 1 that not only have speeds and capacities increased with each generation, but new features have also been implemented such as video calls, interactive multimedia, streaming, and remote control of operations. Introduced in 2019, 5G is thought to be the most ambitious mobile phone network- almost revolutionary in its benefits since 1G. Usually, mobile carriers operate on a 4G LTE and 5G coexistence. This means that 5G phones can switch to 4G if 5G isn’t available in the region. Top of the tower- how? Since the 5G rollout in 2021, Mauritius has been enjoying the larger capacities and speeds of the network. The same question arises: how did this touristic country become a leader in mobile connectivity? There are several factors: - Tourist hotspot - Government initiatives - Improving local infrastructure - General advancements in mobile network technologies - High penetration rates and mobile ownership - Increasing number of connections - Geography Each factor will be considered in turn. Factor 1- Tourist hotspot Every year, Mauritius attracts visitors far and wide to enjoy its mesmerising beaches, luscious escapes and tantalising wildlife. Therefore, over time, mobile network technology has had to improve to meet the communicative needs of tourists. Put differently, tourism significantly supports the telecom industry on the island. Factor 2- Government initiatives As well as providing free, public WiFi hotspots around the island, the government is committed to bridging the digital divide and increasing access to all of its population. Thus, it was announced that, eligible citizens between the ages of 18 and 25 will receive a free, monthly mobile data package (with 4G and 5G capabilities)- starting from the 1st of September 2024. It is an endeavour to include young people in the government’s digital plans, i.e. digital inclusion. Factor 3- Improvements in local infrastructure In recent years, My.t and EmTel have been upgrading their equipment to ensure better coverage and access to 5G in the country. Infrastructure must have improved so that the three mobile operators on the island were granted the license for 5G rollout in June 2021. The current goal is to fully expand 5G coverage in Mauritius. Factor 4- General advancements in mobile network technologies Since its inception in 2019, 5G has had a profound impact on consumers around the globe with its low latency, high resolution streaming, and insanely high speeds and capacities. This pioneering mobile network has rolled out to millions of people, including the citizens of Mauritius island. The government has utilised this new technology to empower its people and pave a way for the country to become a leader in mobile connectivity. Factor 5- High penetration rates and mobile ownership Early 2025 data shows that the East African nation has over 2.1 million active mobile connections, when its population is half of that, a mere 1.261 million. (More mobile connections is not an usual thing as people may have separate connections for personal and work use, for example. Embedded SIMs – eSIMs- have made this possible recently). With this statistic, Mauritius has a high degree of mobile ownership and network connection density. Factor 6- An increase in the number of connections Another recent event is that the number of mobile connections in the nation has been increasing gradually: between 2024 and 2025, the number has increased by 1.9%. Factor 7- Geography It is known that less land- especially less rural land- makes deployment of cell phone towers and installation of masts much easier. Therefore, spanning an area of 2,040 squared kilometres, the main island of Mauritius can enjoy adequate mobile coverage- being one of the smallest African countries. Small island, big signal. To summarise, the above factors contribute to the number one ranking in mobile connectivity for Mauritius. What does Mauritius’s rise mean for the future? If these advancements in infrastructure and technology continue on the island, then there is a brighter outlook for the future. 5G coverage in Mauritius is on its way to completion, ensuring all districts have access to the latest mobile network. Geography, government initiatives, improvements in infrastructure by mobile operators, high number of mobile connections and ownership, are some of the factors that enabled 5G rollout in Mauritius in the first instance. Mauritius is leading by example to the other countries in Africa and is additionally performing well on the global stage for mobile networks. This small island country, usually known for its exotic sights and sugarcane landscape, is quickly overtaking its African neighbours in the race to become the leader in mobile phone connectivity. Written by Manisha Halkhoree Related articles: The future of semiconductor manufacturing / Wireless electricity Project Gallery

Through photonic integration Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link The future of semiconductor manufacturing 11/04/26, 14:43 Last updated: Published: 22/12/23, 15:11 Through photonic integration In December 2023, the researchers from the University of Sydney developed a compact photonic semiconductor chip by heterogeneous material integration methods which integrates an active electro-optic (E-O) modulator and photodetectors in a single chip. The chip functions as a photonic circuit (PIC) offering a 15 gigahertz of tunable frequencies with a spectral resolution of only 37 MHz and is able to expand the radio frequency bandwidth (RF) to precisely control the information flowing within the chip with the help of advanced photonic filter controls. The application of this technology extends to various fields: • Advanced Radar: The chip's expanded radio-frequency bandwidth could significantly enhance the precision and capabilities of radar systems. • Satellite Systems: Improved radio-frequency performance would contribute to more efficient communication and data transmission in satellite systems. • Wireless Networks: The chip has the potential to advance the speed and efficiency of wireless communication networks. • 6G and 7G Telecommunications: This technology may play a crucial role in the development of future generations of telecommunications networks. Microwave Photonics (MWP) is a field that combines microwave and optical technologies to provide enhanced functionalities and capabilities. It involves the generation, processing, and distribution of microwave signals using photonic techniques. An MWP filter is a component used in microwave photonics systems to selectively filter or manipulate certain microwave frequencies using photonic methods (see Figure 1 ). These filters leverage the unique properties of light and its interaction with different materials to achieve filtering effects in the microwave domain. They can be crucial in applications where precise control and manipulation of microwave signals are required. MWP filters can take various forms, including fiber-based filters, photonic crystal filters and integrated optical filters. These filters are designed to perform functions such as wavelength filtering, frequency selection and signal conditioning in the microwave frequency range. They play a key role in improving the performance and efficiency of microwave photonics systems. The MWP filter operates through a sophisticated integration of optical and microwave technologies as depicted in the diagram. Beginning with a laser as the optical carrier, the photonic signal is then directed to a modulator where it interacts with an input Radio-Frequency (RF) signal. The modulator dynamically influences the optical carrier's intensity, phase or frequency based on the RF input. Subsequently, the modulated signal undergoes processing to shape its spectral characteristics in a manner dictated by a dedicated processor. This shaping is pivotal for achieving the desired filtering effect. The processed optical signal is then fed into a photodiode for conversion back into an electrical signal. This conversion is based on the variations induced by the modulator on the optical carrier. The final output which is represented by the electrical signal reflects the filtered and manipulated RF signal which demonstrates the MWP's ability in leveraging both optical and microwave domains for precise and high-performance signal processing applications. Extensive research has been conducted in the field of MWP chips, as evidenced by a thorough examination in Table 1 . This table compares recent studies based on chip material type, filter type, on-chip component integration, and working bandwidth. Notably, previous studies demonstrated noteworthy advancements in chip research despite the dependence on external components. What distinguishes the new chip is its revolutionary integration of all components into a singular chip which is a significant breakthrough that sets it apart from previous attempts in the field. Here the term "On-chip E-O" involve the integration of electro-optical components directly onto a semiconductor chip or substrate. This integration facilitates the interaction between electrical signals (electronic) and optical signals (light) within the same chip. The purpose is to enable the manipulation, modulation or processing of optical signals using electrical signals typically in the form of voltage or current control. Key components of on-chip electro-optical capabilities include: 1. Modulators which alter the characteristics of an optical signal in response to electrical input which is crucial for encoding information onto optical signals. 2. Photonic detectors convert optical signals back into electrical signals extracting information for electronic processing. 3. Waveguides guide and manipulate the propagation of light waves within the chip, routing optical signals to various components. 4. Switches routes or redirects the optical signals based on electrical control signals. This integration enhances compactness, energy efficiency, and performance in applications such as communication systems and optical signal processing. "FSR-free operation" refers to Free Spectral Range (FSR) which is a characteristic of optical filters and resonators. FSR is the separation in frequency between two consecutive resonant frequencies or transmission peaks. The column "FSR-free operation" indicates whether the optical processing platform operates without relying on a specific or fixed Free Spectral Range. It means that its operation is not bound or dependent on a particular FSR. This could be advantageous in scenarios where flexibility in the spectral range or the ability to operate over a range of frequencies without being constrained by a specific FSR is desired. "On-chip MWP link improvement" refers to enhancements made directly on a semiconductor chip to optimize the performance of MWP links. These improvements aim to enhance the integration and efficiency of communication or signal processing links that involve both microwave and optical signals. The term implies advancements in key aspects such as data transfer rates, signal fidelity and overall link performance. On-chip integration brings advantages such as compactness and reduced power consumption. The manufacturing of the photonic integrated circuit (PIC) involves partnering with semiconductor foundries overseas to produce the foundational chip wafer. This new chip technology will play a crucial role in advancing independent manufacturing capabilities. Embracing this type of chip architecture enables a nation to nurture the growth of its autonomous chip manufacturing sector by mitigating reliance on international foundries. The extensive chip delays witnessed during the 2020 COVID pandemic underscored the global realisation of the chip market's significance and its potential impact on electronic manufacturing. Written by Arun Sreeraj Related articles: Advancements in semi-conductor technology / The search for a room-temperature superconductor / Silicon hydrogel lenses / Mobile networks Project Gallery

Discussing Peto's Paradox in cancer Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Why blue whales don't get cancer 11/04/26, 13:57 Last updated: Published: 16/10/23, 21:22 Discussing Peto's Paradox in cancer Introduction: What is Peto’s Paradox? Cancer is a disease that occurs when cells divide uncontrollably, owing to genetic and epigenetic factors . Theoretically, the more cells an organism possesses, the higher the probability should be for it to develop cancer. Imagine that you have one tiny organism – a mouse, and a huge organism – an elephant. Since an elephant has more cells than a mouse, it should have a higher chance of developing cancer, right? This is where things get mysterious. In reality, animals with 1,000 times more cells than humans are not more likely to develop cancer. Notably, blue whales, the largest mammals, hardly develop cancer. Why? In order to understand this phenomenon, we must dive deep into Peto’s Paradox. Peto’s paradox is the lack of correlation between body size and cancer risk. In other words, the number of cells you possess does not dictate how likely you are to develop cancer. Furthermore, research has shown body mass and life expectancy are unlikely to impact the risk of death from cancer . (see figure 1) Peto’s Paradox: Protective Mechanisms Mutations, otherwise known as changes or alterations in the deoxyribonucleic acid (DNA) sequence, play a role in cancer and ageing. Research scientists have analysed mutations in the intestines of several mammalian species , ranging from mice, monkeys, cats, dogs, humans, and giraffes, to tigers and lions. Their results reveal that these mutations mostly come from processes that occur inside the body, such as chemicals causing changes in DNA. These processes were similar in all the animals they studied, with slight differences. Interestingly, annually, animals with longer lifespans were found to have fewer mutations in their cells ( figure 2 ). These findings suggest that the rate of mutations is associated with how long an animal lives and might have something to do with why animals age. Furthermore, even though these animals have very different lifespans and sizes, the amount of mutations in their cells at the end of their lives was not significantly different – this is known as cancer burden. Since animals with a larger size or longer lifespan have a larger number of cells (and hence DNA) that could undergo mutation, and a longer time of exposure to mutations, how is it possible that they do not have a higher cancer burden? Evolution has led to the formation of mechanisms in organisms that suppress the development of cancerous cells . Animals possessing 1,000 times as many cells as humans do not display a higher susceptibility to cancer, indicating that natural mechanisms can suppress cancer roughly 1,000 times more efficiently than they operate in human cells . Does this mean larger animals have a more efficient protective mechanism against cancer? A tumour is an abnormal lump formed by cells that grow and multiply uncontrollably. A tumour suppressor gene acts like a bodyguard in your cells. They help prevent the uncontrollable division of cells that could form tumours. Previous analyses have shown that the addition of one or two tumour suppressor gene mutations would be sufficient to reduce the cancer risk of a whale to that of a human. However, evidence does not suggest that an increased number of tumour suppressor genes correlated with increasing body mass and longevity. Although a study by Caulin et al . identified biomarkers in large animals that may explain Peto’s paradox, more experiments need to be conducted to confirm the biological mechanisms involved. Just over a month ago, an investigation of existing evidence on such mechanisms revealed a list of factors that may contribute to Peto’s paradox. This includes replicative immortality, cell senescence, genome instability and mutations, proliferative signalling, growth suppression evasion and cell resistance to death. As far as we know, different strategies have been followed to prevent cancer in species with larger sizes or longer lifespans . However, more studies must be conducted in the future in order to truly explain Peto’s paradox. Peto’s Paradox: Other Theories There are several theories that attempt to explain Peto’s paradox. One of which explains that large organisms have a lower basal metabolic rate, leading to less reactive oxygen species. This means that cells in larger organisms incur less oxidative damage, causing a lower mutation rate and lower risk of developing cancer. Another popular theory is the formation of hypertumours . As cells divide uncontrollably in a tumour, “cheaters” could emerge. These “cheaters”, known as hypertumours, are cells which grow and feed on their original tumour, ultimately damaging or destroying the original tumour. In large organisms, tumours have more time to reach lethal size. Therefore, hypertumours have more time to evolve, thereby destroying the original tumours. Hence, in large organisms, cancer may be more common but is less lethal. Clinical Implications Curing cancer has posed significant challenges. Consequently, the focus on cancer treatment has shifted towards cancer prevention . Extensive research is currently underway to investigate the behaviour and response of cancer cells to the treatment process. This is done through a multifaceted approach; investigating the tumour microenvironment and diagnostic or prognostic biomarkers. Going forward, a deeper understanding of these fields enables the development of prognostic models as well as targeted treatment methods. One example of an exciting discovery is the revelation of TP53 . The discovery of this tumour suppressor gene indicates that it plays a role in making elephant cells more responsive to DNA damage and in triggering apoptosis by regulating the TP53 signaling pathway. These findings imply that having more copies of TP53 may have directly contributed to the evolution of extremely large body sizes in elephants, helping resolve Peto’s paradox . Particularly, there are 20 copies of the TP53 gene in elephants, but only one copy of the TP53 gene in humans (see figure 3 ). Through more robust studies and translational medicine, it would be fascinating to see how such discoveries could be applied into human medicine ( figure 4 ). Conclusion The complete mechanism of how evolution has enabled organisms that are larger in size and have longer lifespans than humans is still a mystery. There is a multitude of hypotheses that need to be extensively investigated with large-scale experiments. By unravelling the mysteries of Peto’s paradox, these studies could provide invaluable insights into cancer resistance and potentially transform cancer prevention strategies for humans. Written by Joecelyn Kirani Tan Related articles: Biochemistry of cancer / Orcinus orca (killer whale) / Canine friends and cancer Project Gallery

The novelty of quantum computing Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link Understanding Quantum Computing and Its Applications 11/04/26, 13:50 Last updated: Published: 03/06/23, 17:18 The novelty of quantum computing Relative to the inception of modern technology, quantum computing is fairly young. In 1998, Isaac Chuang of the Los Alamos National Laboratory, Neil Gershenfeld of the Massachusetts Institute of Technology (MIT), and Mark Kubinec of the University of California at Berkeley created the first quantum computer that could be loaded with data and output a solution. This marked a significant breakthrough moment for the world of computing and technology. To understand quantum computing, we must first delve into the basics of a regular computer. At the core, a computer operates based on a binary system of 1s and 0s, akin to an on/off switch. However, quantum computers go beyond this simplicity. Quantum computers utilize quantum bits, or qubits, which can exist in a superposition of states, representing both 0 and 1 simultaneously. This property allows quantum computers to perform parallel computations and leverage quantum phenomena like entanglement and interference to solve certain problems more efficiently than classical computers. Superposition, the ability of qubits to exist in multiple states simultaneously, is one of the unique properties of quantum mechanics that enables quantum computers to perform computations differently than classical computers. It offers new possibilities for information processing and solving complex tasks. One notable recent project in the field of quantum computing involved Google's use of a 53-qubit quantum computer named Sycamore. This quantum computer successfully performed a computation that would have taken the most powerful classical supercomputers thousands of years to complete, accomplishing it in just a few minutes. This research project exemplified the immense potential of quantum computers for tackling complex problems in a remarkable manner. As we continue to unlock the mysteries of quantum computing and overcome technical challenges, we stand at the brink of a new era of innovation and discovery. From advancements in drug discovery and optimization to revolutionizing cryptography and financial modelling, the possibilities are immense. The progress made so far in quantum computing is incredibly promising (it will soon be ready for commercialisation), and it is an exciting field that holds the key to tackling some of the world's most pressing challenges. Written by Jaspreet Mann Related articles: Quantum chemistry / Computational organic chemistry REFERENCES Chuang, I., Gershenfeld, N., & Kubinec, M. (1998). Experimental implementation of fast quantum searching. Physical Review Letters, 80(15), 3408–3411. Nielsen, M. A., & Chuang, I. L. (2010). Quantum Computation and Quantum Information: 10th Anniversary Edition. Cambridge University Press. Arute, F., et al. (2019). Quantum supremacy using a programmable superconducting processor. Nature, 574(7779), 505–510. Daskin, A., et al. (2021). Quantum Computing: Progress and Prospects. National Academies Press. Project Gallery

AI has long been a controversial topic, with some people fearing its potential consequences. This has been exacerbated by popular culture, with movies such as "The Terminator" and "2001: A Space Odyssey" depicting AI systems becoming self-aware and turning against humans. Go back Facebook X (Twitter) WhatsApp LinkedIn Pinterest Copy link The evolution of AI: understanding the role of NLP technologies Last updated: 11/04/26 Published: 08/05/23 Artificial intelligence (AI) has long been a controversial topic, with some people fearing its potential consequences. This has been exacerbated by popular culture, with movies such as The Terminator and 2001: A Space Odyssey depicting AI systems becoming self-aware and turning against humans. Similarly, The Matrix portrayed a dystopian future where AI systems had enslaved humanity. Fast forward to the present day- AI has become a normal part of our everyday life, whether we realise it or not. From virtual assistants like Siri and Alexa to personalised movie and product recommendations, AI-powered technologies have revolutionised the way we interact with technology. AI also plays a critical role in industries such as healthcare, finance, and transportation, with algorithms helping to analyse data, identify patterns, and make predictions that lead to better decision-making. As with any industry, the AI industry is very much prone to evolution. In fact, this is especially relevant for the AI industry, given that it engages user habits to learn and redefine its understanding. This has led to the introduction of unforeseen technologies. One of the most studied and developed AI modelling techniques, Natural Language Processing (NLP), has been particularly placed under focus recently with the emergence of technologies such as Open AI’s ChatGPT, Google’s Gemini (formerly Bard) AI and Microsoft’s Bing AI- known as Copilot. ChatGPT in particular, was one of the first technologies of this kind to garner significant fame. Within its first year of release, the GPT-3 model had more than 10,000 registered developers and over 300 applications built on its application programming interface (API). In addition, Microsoft acquired OpenAI's exclusive license to the GPT-3 technology in 2020, further solidifying its position as a leading language model in the industry. ChatGPT works as an advanced artificial intelligence technology designed to understand and process human language. Built on the GPT-3.5 architecture, it uses NLP to comprehend and generate responses that simulate human conversation. ChatGPT is classified as a large language model, which means it has been trained on vast amounts of data and can generate high-quality text that is both coherent and relevant to the input provided. While concerns have been raised about the potential impact of NLP technologies, there are several reasons why we should not fear their emergence. Firstly, NLP has already enabled a wide range of useful applications that have the potential to improve efficiency, convenience, and accessibility. Furthermore, the development and deployment of NLP technologies is subject to ethical considerations and regulations that aim to ensure their responsible use. NLP technologies are not designed to replace humans, but rather to complement and enhance human capabilities. While some jobs may be impacted by automation, new jobs are likely to emerge that require human skills that are not easily replicated by machines. Ultimately, the impact of NLP technologies depends on how they are developed and used. There are always likely to be risks, but by taking a proactive approach to their development and deployment, we can ensure that they are used to benefit society and advance human progress. Written by Jaspreet Mann Related articles: AI: the good, the bad, and the future / Latent space transformations / Markov chains REFERENCES Hirschberg, Julia, and Christopher D. Manning. “Advances in Natural Language Processing.” Science, vol. 349, no. 6245, July 2015, pp. 261–66. DOI.org (Crossref), https://doi.org/10.1126/science.aaa8685. What Is Natural Language Processing? | IBM. https://www.ibm.com/topics/natural-language-processing. Accessed 1 May 2023. Biswas, Som S. “Role of Chat GPT in Public Health.” Annals of Biomedical Engineering, vol. 51, no. 5, May 2023, pp. 868–69. Springer Link, https://doi.org/10.1007/s10439-023-03172-7. Davenport, T.H. (2018). The AI Advantage: How to Put the Artificial Intelligence Revolution to Work. MIT Press. Bird, S., Klein, E., & Loper, E. (2009). Natural Language Processing with Python. O'Reilly Media.