Daily Archives: October 20, 2024

Using Science to Bring Literature to Life

Too often when we consider how to connect science and literacy, we think about using literature to support science. Maybe it’s reading a fictional book with a science theme, or exploring a biography of a famous scientist.But we could instead turn that around and use science experiments as a way of bringing literature to life. Or we could use literature as a way to explore some of the questions about design and ethics that arise in the work of science.As educators in Chicago, we saw that regardless of the setting, many students were not interested in science. They saw it as facts and rote memorization. In both our classwork and our outside workshops, we needed to create more meaningful connections to the sciences, and incorporating literature allowed students to engage in a different way.The stories suddenly became something students could see, feel, and experience. They could see science as being creative. Showing students how scientific concepts connect to things that they’re passionate about allows them to gain confidence in science. It also challenges them to move beyond the traditional expectations of science classwork to become more open-minded and think creatively.How We’ve Done ItUsing science as a support to engage students with complicated texts: Beowulf is a classic story filled with monsters, a venomous fire-breathing dragon, undersea scrimmages, and battle descriptions including torn limbs and bloody, severed heads—like your basic video game.Yet many of the high school students we’ve worked with were completely turned off because they found the language too difficult. Even when trying a variety of drawing and role-playing activities, it was still hard to get all of our students to completely engage.So we created a series of science lessons to make the story more tangible. In one lesson, students are challenged to create their own 3D model of Grendel, Grendel’s mother, or the dragon. They must support their ideas by citing evidence from the text, and make and explain inferences where specific descriptions are not available. Students create paper robots, and learn the science behind circuitry by using LEDs to make their monsters light up. Battery-powered motors make the robots move.Taking the lesson further, students can develop an arena where they set up their moving monsters to “fight” a Beowulf character. We discuss the probability of the outcomes, and discuss behavioral and physical characteristics of predators that occur in nature: What adaptations aid predators to overcome their prey? Which of these adaptations would need to occur in a monster in order for it to defeat Beowulf?Students gain a deeper sense of the literature by thinking about alternate scenarios such as: What if Beowulf had lost to Grendel? What would it mean to our sense of the poem if Beowulf did not kill the dragon?The lessons also incorporate chemistry, anatomy, and physiology to deepen inquiry and connections. We “myth-bust” to see if these events and monsters could really exist. What is a venomous dragon, and what toxins would the dragon secrete that would make it venomous? What would a fire-breathing dragon’s diet consist of to enable it to breathe fire? What would really happen if an arm was torn off in battle?Using literature to help students understand the idea of responsibility in science: We hit upon the idea of using the story of Frankenstein to help make a potentially dry science unit on circuits more engaging. With students from the mid-elementary grades and up, we don’t read the novel but instead work with quotes from it to expand on what they know about the character, create deeper discussions, and incorporate reading comprehension skills.We use Frankenstein’s monster to connect students to ideas of design and ethics in science. We role-play as our own Dr. Frankenstein, collecting a series of items to cobble together to build our own unique creatures. We learn about motors and circuitry to bring our mini-robots to life.After going through the process as creators, students reflect on how much of their process was spent on bringing their creature to life vs. considering the design and function of their creature. This idea reconnects us to a deeper theme in the story—because the creature Dr. Frankenstein created is so ugly, people assume it’s evil. The creature looks at Frankenstein and says, “Accursed creator! Why did you form a monster so hideous that even you turned from me in disgust?”Since people expect it to act like a monster, the creature eventually becomes one.Students are then challenged to consider these questions:If Frankenstein created a beautiful creature, would people have responded to it differently?What was your process when you were deciding how your creature would look?What responsibility do scientists and inventors have to focus on the design as much as the purpose of their creation?What We’ve Seen After These LessonsThese lessons draw in the students who don’t see themselves as scientists—they come to see that creativity can be a part of science. And they build confidence as they realize that science is broad—not just a singular subject. The lessons challenge the science-minded students to expand and think more creatively. And they’ve drawn many students toward independent reading and inquiry.

Using Science to Bring Literature to Life

Too often when we consider how to connect science and literacy, we think about using literature to support science. Maybe it’s reading a fictional book with a science theme, or exploring a biography of a famous scientist.But we could instead turn that around and use science experiments as a way of bringing literature to life. Or we could use literature as a way to explore some of the questions about design and ethics that arise in the work of science.As educators in Chicago, we saw that regardless of the setting, many students were not interested in science. They saw it as facts and rote memorization. In both our classwork and our outside workshops, we needed to create more meaningful connections to the sciences, and incorporating literature allowed students to engage in a different way.The stories suddenly became something students could see, feel, and experience. They could see science as being creative. Showing students how scientific concepts connect to things that they’re passionate about allows them to gain confidence in science. It also challenges them to move beyond the traditional expectations of science classwork to become more open-minded and think creatively.How We’ve Done ItUsing science as a support to engage students with complicated texts: Beowulf is a classic story filled with monsters, a venomous fire-breathing dragon, undersea scrimmages, and battle descriptions including torn limbs and bloody, severed heads—like your basic video game.Yet many of the high school students we’ve worked with were completely turned off because they found the language too difficult. Even when trying a variety of drawing and role-playing activities, it was still hard to get all of our students to completely engage.So we created a series of science lessons to make the story more tangible. In one lesson, students are challenged to create their own 3D model of Grendel, Grendel’s mother, or the dragon. They must support their ideas by citing evidence from the text, and make and explain inferences where specific descriptions are not available. Students create paper robots, and learn the science behind circuitry by using LEDs to make their monsters light up. Battery-powered motors make the robots move.Taking the lesson further, students can develop an arena where they set up their moving monsters to “fight” a Beowulf character. We discuss the probability of the outcomes, and discuss behavioral and physical characteristics of predators that occur in nature: What adaptations aid predators to overcome their prey? Which of these adaptations would need to occur in a monster in order for it to defeat Beowulf?Students gain a deeper sense of the literature by thinking about alternate scenarios such as: What if Beowulf had lost to Grendel? What would it mean to our sense of the poem if Beowulf did not kill the dragon?The lessons also incorporate chemistry, anatomy, and physiology to deepen inquiry and connections. We “myth-bust” to see if these events and monsters could really exist. What is a venomous dragon, and what toxins would the dragon secrete that would make it venomous? What would a fire-breathing dragon’s diet consist of to enable it to breathe fire? What would really happen if an arm was torn off in battle?Using literature to help students understand the idea of responsibility in science: We hit upon the idea of using the story of Frankenstein to help make a potentially dry science unit on circuits more engaging. With students from the mid-elementary grades and up, we don’t read the novel but instead work with quotes from it to expand on what they know about the character, create deeper discussions, and incorporate reading comprehension skills.We use Frankenstein’s monster to connect students to ideas of design and ethics in science. We role-play as our own Dr. Frankenstein, collecting a series of items to cobble together to build our own unique creatures. We learn about motors and circuitry to bring our mini-robots to life.After going through the process as creators, students reflect on how much of their process was spent on bringing their creature to life vs. considering the design and function of their creature. This idea reconnects us to a deeper theme in the story—because the creature Dr. Frankenstein created is so ugly, people assume it’s evil. The creature looks at Frankenstein and says, “Accursed creator! Why did you form a monster so hideous that even you turned from me in disgust?”Since people expect it to act like a monster, the creature eventually becomes one.Students are then challenged to consider these questions:If Frankenstein created a beautiful creature, would people have responded to it differently?What was your process when you were deciding how your creature would look?What responsibility do scientists and inventors have to focus on the design as much as the purpose of their creation?What We’ve Seen After These LessonsThese lessons draw in the students who don’t see themselves as scientists—they come to see that creativity can be a part of science. And they build confidence as they realize that science is broad—not just a singular subject. The lessons challenge the science-minded students to expand and think more creatively. And they’ve drawn many students toward independent reading and inquiry.

NTU scientists revolutionize ceramic microparticle fabrication with ancient construction technique

SINGAPORE: Scientists at Nanyang Technological University (NTU) Singapore have harnessed an ancient East Asian building method to fabricate advanced ceramic microparticles measuring just slightly larger than the width of a human hair.
This innovative technique, inspired by the traditional “tongue and groove” joinery, promises to reshape the micro-manufacturing landscape across various high-tech sectors.

The new fabrication method has led to the developing of a microfluidic chip capable of producing and shaping ceramic microparticles with remarkable precision and complexity.
These microparticles, which can take on intricate forms such as ten-toothed gears and triangular structures with angled edges, open doors to a myriad of applications in microelectronics, aerospace, energy, and medical and mechanical engineering.

Traditional methods like micromachining and laser sintering have faced significant challenges in achieving the desired resolution and production capabilities for these diminutive and detailed shapes.
Specifically, these conventional techniques struggle to produce sharp-edged, non-transparent microparticles due to the inherent material properties and the minuscule sizes involved.
The NTU researchers’ new approach dramatically improves production efficiency, increasing the output rate by as much as tenfold compared to existing techniques.
Moreover, it ensures a level of quality previously unattainable in micro-ceramic manufacturing.
The inspiration for this innovative microfluidic chip stems from a historical construction technique known as “mortise and tenon” joinery.
This method, which utilizes interlocking grooves and tongues to connect wooden structures without needing nails or glue, has a rich history in East Asia.
It dates back to as early as 1000 BC in ancient China, where it was used to construct palatial residences.
The technique was further adopted in Korea from the 14th century onward and is seen in the construction of traditional Japanese temples.
Notably, it continues to play a vital role in Korean architecture, particularly in the “Hanok” style and was employed in the iconic Gyeongbokgung Palace in Seoul.

NTU scientists revolutionize ceramic microparticle fabrication with ancient construction technique

SINGAPORE: Scientists at Nanyang Technological University (NTU) Singapore have harnessed an ancient East Asian building method to fabricate advanced ceramic microparticles measuring just slightly larger than the width of a human hair.
This innovative technique, inspired by the traditional “tongue and groove” joinery, promises to reshape the micro-manufacturing landscape across various high-tech sectors.

The new fabrication method has led to the developing of a microfluidic chip capable of producing and shaping ceramic microparticles with remarkable precision and complexity.
These microparticles, which can take on intricate forms such as ten-toothed gears and triangular structures with angled edges, open doors to a myriad of applications in microelectronics, aerospace, energy, and medical and mechanical engineering.

Traditional methods like micromachining and laser sintering have faced significant challenges in achieving the desired resolution and production capabilities for these diminutive and detailed shapes.
Specifically, these conventional techniques struggle to produce sharp-edged, non-transparent microparticles due to the inherent material properties and the minuscule sizes involved.
The NTU researchers’ new approach dramatically improves production efficiency, increasing the output rate by as much as tenfold compared to existing techniques.
Moreover, it ensures a level of quality previously unattainable in micro-ceramic manufacturing.
The inspiration for this innovative microfluidic chip stems from a historical construction technique known as “mortise and tenon” joinery.
This method, which utilizes interlocking grooves and tongues to connect wooden structures without needing nails or glue, has a rich history in East Asia.
It dates back to as early as 1000 BC in ancient China, where it was used to construct palatial residences.
The technique was further adopted in Korea from the 14th century onward and is seen in the construction of traditional Japanese temples.
Notably, it continues to play a vital role in Korean architecture, particularly in the “Hanok” style and was employed in the iconic Gyeongbokgung Palace in Seoul.

Political Scientist: The Kremlin May ‘Split On’ Lukashenka

11

20.10.2024, 12:47
12,510

The dictator is totally unsure wether Moscow will take care of his interests.

On October 17, at a meeting with scientists and participants in Antarctic expeditions in Minsk, Lukashenka suddenly declared: if Belarus is not represented at the proposed negotiations on ending the Russian-Ukrainian war, it may lose up to half of its territory.He did not explain how exactly this could happen, writes political analyst Aliaksandr Klaskouski on Pozirk.But he did say a revealing phrase: “I have always insisted — I told the Ukrainians and warned Putin: Belarusians must be present at the negotiations on Ukraine.”This “warned Putin” indirectly shows: Lukashenka is totally unsure wether Moscow will take care of his interests when the conversation turns to a new alignment in the region, a new system of international security.And in general, no matter how much you boast about your alliance with Russia, the collapse of relations with the West is a very uncomfortable matter.

PATREON
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Political Scientist: The Kremlin May ‘Split On’ Lukashenka

11

20.10.2024, 12:47
12,524

The dictator is totally unsure wether Moscow will take care of his interests.

On October 17, at a meeting with scientists and participants in Antarctic expeditions in Minsk, Lukashenka suddenly declared: if Belarus is not represented at the proposed negotiations on ending the Russian-Ukrainian war, it may lose up to half of its territory.He did not explain how exactly this could happen, writes political analyst Aliaksandr Klaskouski on Pozirk.But he did say a revealing phrase: “I have always insisted — I told the Ukrainians and warned Putin: Belarusians must be present at the negotiations on Ukraine.”This “warned Putin” indirectly shows: Lukashenka is totally unsure wether Moscow will take care of his interests when the conversation turns to a new alignment in the region, a new system of international security.And in general, no matter how much you boast about your alliance with Russia, the collapse of relations with the West is a very uncomfortable matter.

PATREON
Support the website

You can support the website Charter97.org

MULTI-CURRENCY ACCOUNT FOR ASSISTANCE:
Bank’s name: Bank Millennium S.A.Address: ul. Stanislawa Zaryna, 2A, 02-593, WarszawaIBAN: PL97116022020000000216711123SWIFT: BIGBPLPWName of the account holder: Fundacja “KARTA ‘97”Purpose/title of payment: Donation for statuary aimsYou can contact us by the e-mail [email protected]

Follow Charter97.org social media accounts