Explore Marie Curie’s groundbreaking legacy in this comprehensive blog post. Embedded with the podcast episode, you’ll find:

1. Key Summaries: Her Nobel achievements, wartime innovations, and tragic sacrifices.
2. Original Transcript: The raw conversation dissecting her life and scientific impact.
3. Galaxy AI Insights: A concise breakdown of her contributions to cancer treatment, X-ray technology, and atomic science.
4. Legacy Connections: How her work influenced Rosalind Franklin’s DNA research and Linus Pauling’s peace activism.

Perfect for science enthusiasts, educators, and history buffs seeking a deep dive into the woman who lit up the invisible world of radioactivity.

Listen to “Radioactive Resilience: The Marie Curie Chronicles” on Spreaker.

Marie Curie: A Legacy of Scientific Tenacity and Innovation

1. Pioneering Discoveries in Radioactivity
Marie Curie, born Maria Skłodowska in 1867, overcame gender barriers in science to become the first woman awarded a Nobel Prize. Her groundbreaking work with Pierre Curie led to the discovery of polonium (named after her homeland, Poland) and radium, elements that revolutionized the understanding of radioactivity—a term she coined. Their research on uranium and thorium’s radioactive properties earned them the 1903 Nobel Prize in Physics, shared with Henri Becquerel.

2. Challenges and Sacrifices
The Curies labored under harsh conditions in a rudimentary lab, isolating radium from tons of pitchblende. Their dedication came at a personal cost: Pierre died tragically in 1906 from a street accident, and Marie later succumbed to aplastic anemia in 1934, likely due to prolonged radiation exposure. Despite these hardships, she persisted, becoming the first person to win a second Nobel (Chemistry, 1911) for isolating pure radium.

3. Wartime Contributions and Medical Legacy
During WWI, Curie championed mobile X-ray units (“Little Curies”), training personnel and driving units to the frontlines, saving countless soldiers. Her work laid the foundation for radiation therapy in cancer treatment, emphasizing targeted tumor destruction—a principle refined in modern medicine with precise imaging and dosing techniques.

4. Scientific Influence and Gender Advocacy
Curie’s research influenced future scientists like Rosalind Franklin, whose X-ray diffraction studies (inspired by Curie’s work) were pivotal in discovering DNA’s structure. As the first female Nobel laureate and sole winner in two scientific fields, Curie shattered gender norms, advocating for women in STEM and inspiring generations.

5. Linus Pauling: A Brief Interlude
The podcast briefly highlights Linus Pauling, another dual Nobel laureate (Chemistry, 1954; Peace, 1962), noted for his work on chemical bonds and anti-nuclear activism. His 1968 paper on orthomolecular psychiatry (treating mental illness via nutrient adjustment) is mentioned, with plans for a future deep dive.

6. Reflections on Legacy
Curie’s story underscores the paradox of scientific progress: her discoveries saved lives yet claimed her own. Her perseverance amidst societal and personal adversity cements her as an icon of resilience. The episode concludes by linking her legacy to broader scientific advancements, emphasizing the importance of recognizing overlooked contributors like Rosalind Franklin.

Key Takeaways

• Innovation Through Adversity: Curie’s work exemplifies how tenacity drives scientific breakthroughs.
• Ethical Responsibility: Early radiation research highlights the need for safety protocols in scientific exploration.
• Interconnected Discoveries: Curie’s foundational work enabled later breakthroughs in fields from oncology to genetics.

Marie Curie’s life reminds us that curiosity, coupled with courage, can illuminate the darkest unknowns—even at great personal cost.

Galaxy AI transcript summary:

Radioactivity Discoveries

• Scientific investigations explore the natural world through experiments and observation.
• Marie Curie’s groundbreaking work on radioactivity is a prime example.
• Curie was the first woman to win a Nobel Prize and the only person to win it twice in different scientific fields.

Double Nobel Laureate: Marie Curie’s Scientific Achievements

• Marie Curie was the first person to win Nobel Prizes in two different scientific fields: Physics and Chemistry.
• Her discoveries included the elements polonium and radium.
• Curie’s work contributed significantly to the development of X-rays.

Linus Pauling’s Scientific Contributions

• The speaker expresses familiarity with Linus Pauling’s work, particularly his 1968 paper on orthomolecular psychiatry.
• Pauling’s pioneering research focused on the chemical bond, molecular structure, and orthomolecular psychiatry.
• A discussion of Pauling’s specific contributions to chemistry and orthomolecular psychiatry is proposed for a future conversation.

Linus Pauling and Marie Curie: Nobel Laureates

• Linus Pauling received the Nobel Prize in Chemistry for chemical bond research and the Nobel Peace Prize for his activism against nuclear weapons testing.
• Marie Curie, born Maria Skłodowska, faced educational barriers as a woman in Poland but pursued studies in Paris after working as a governess.
• A governess provided education to children in their homes, a common profession for educated women during that era.

Governesses and the Dawn of Radioactivity

• Governesses provided early forms of home schooling, educating children within the home.
• Marie Curie’s education and subsequent career in physics and mathematics are highlighted.
• Curie coined the term ‘radioactivity’ to describe the emission of rays from elements like uranium and thorium.

Radioactive Discoveries of the Curies

• Uranium and thorium’s effect on photographic plates, similar to X-rays, was a crucial finding in understanding radioactivity.
• The discovery of thorium’s radioactivity happened in 1898, a few years after uranium’s radioactivity was discovered in 1896.
• Polonium, named after Poland, and radium were discovered in 1898 by Marie and Pierre Curie.

Radium’s Discovery and Properties

• Radium’s name originates from its intense radioactivity, a characteristic observed by Curie.
• Its radioactivity is significantly stronger than that of uranium and thorium.
• The discussion shifts to focusing on the discoveries of historical figures and their impact.

Radium Isolation: A Scientific Breakthrough

• The isolation of pure radium, a radioactive element, was a significant scientific achievement.
• This process involved four years of arduous work using basic equipment in challenging conditions.
• The discovery earned a Nobel Prize in Physics in 1903.

Tragic End of a Scientific Collaboration

• Clear Carey’s research was tragically cut short in 1906 due to an accident.
• Marie Curie continued the work despite health consequences from radiation exposure, eventually succumbing to aplastic anaemia in 1934.
• Pierre Curie’s death in a street accident in 1906 involved a horse-drawn wagon on a rain-slicked street.

Celebrating Marie Curie’s Scientific Contributions

• Marie Curie’s discovery of radium revolutionized cancer treatment through radiation therapy.
• Curie also developed portable X-ray machines, significantly aiding medical care during wartime.
• These mobile X-ray units, nicknamed ‘Little Curies,’ were crucial for diagnosing injuries and saving lives.

Marie Curie’s Wartime Contributions and Scientific Legacy

• Marie Curie’s World War I contributions involved developing and deploying X-ray equipment, personally training personnel, and driving vehicles to the front lines.
• Her dedication significantly impacted battlefield medicine, saving numerous lives.
• Curie’s X-ray research laid the groundwork for later discoveries concerning DNA structure, influencing Watson and Crick’s work.

Rosalind Franklin and Marie Curie: X-ray Pioneering

• Rosalind Franklin’s contribution to the discovery of DNA’s structure was often underestimated.
• Franklin’s expertise in X-ray diffraction, influenced by Marie Curie’s research, was vital in creating images for the DNA model.
• Marie Curie was born in 1867, and Rosalind Franklin in 1920.

Rosalind Franklin and X-ray Diffraction in France

• Rosalind Franklin utilized X-ray diffraction techniques in Paris, starting in 1946.
• These techniques were prominent in France due to Marie Curie’s contributions.
• Marie Curie’s work with mobile X-ray units during World War I is highlighted.

Marie Curie’s Radioactivity Research and Legacy

• Marie Curie’s post-war research focused on using radiation for cancer treatment.
• Her work resulted in new cancer treatment techniques still used today.
• Ironically, Curie’s groundbreaking research with radioactivity ultimately caused her death.

Radiation Exposure and its Health Consequences

• A death in 1934 resulted from aplastic anaemia, likely due to prolonged radiation exposure.
• The lack of safety protocols in early scientific research highlighted the dangers of radiation.
• The book ‘Ready, Radiation: Rare, the History of Beer and Misunderstanding of Radiation’ offers insights into radiation’s effects on the body.

Exploring Emotional and Physical Radiation Effects

• A discussion about the book ‘Radiation’ by Robert Peter Gayle MD and Eric Lax.
• Correction made, referencing ‘Emotional Radiation’ and its focus on radiation’s effects on the body.
• A transition to discussing Marie Curie’s contributions to the field, with a time constraint of 5 minutes remaining.

Marie Curie’s Radiation Research

• Marie Curie’s later research centered on applying radiation for cancer treatment.
• She championed radium’s use in treating lupus and certain forms of paralysis.
• The long-term effects of radiation were not fully understood during that era.

Evolution of Radiation Therapy

• Early radium treatments for non-cancerous conditions proved ineffective and hazardous due to high radiation exposure.
• Modern radiation therapy employs precise machines for targeted tumor treatment, minimizing harm to healthy tissues.
• Advanced imaging techniques enable accurate tumor mapping before treatment, improving precision.

Marie Curie’s Scientific Legacy

• Marie Curie was the first woman to win a Nobel Prize and the only woman to win in two different scientific fields.
• Her research significantly advanced the scientific world.
• Her dedication to research despite significant challenges is inspiring.

A Radio Show Recap: Marie Curie’s Life and Legacy

• The show explored Marie Curie’s life, from her radioactivity discoveries to her wartime contributions and cancer research.
• Her influence on Rosalind Franklin’s X-ray diffraction work, vital to DNA understanding, was also discussed.
• The broadcast concluded with thanks to listeners for joining the exploration of Curie’s remarkable scientific achievements.

A Legacy in Science and Peace

• Exploration of a prominent figure’s contributions to chemistry, biochemistry, and peace activism.
• Significant advancements in understanding molecular structures are highlighted.
• The Nobel Peace Prize was awarded for advocacy against nuclear weapons testing.

UnEdited Galaxy AI TranScript from S24 Ultra

Speaker 1 is Hakeem Ali-Bocas Alexander and Speaker is Vega

Speaker 1 (00:00)
Ahead and repeat what you just said. So we can get the second podcast gone.

Speaker 2 (00:07)
Sure thing, scientific investigations are all about exploring the natural world through experiment in observation, we could look at famous scientific discoveries like how Marie Curie discovered radioactivity, or maybe explored the scientific method itself. Does either of those sound interesting to you?

Speaker 1 (00:26)
Well, I am a big fan of Marie Curie anxio. It has been somewhat underserved for a long period of time, although people are doing their best to make sure she’s known for her work, but let’s start with her anyway, I think it’s a great place to start.

Speaker 2 (00:45)
Great Marie curry was a brilliant scientist who made groundbreaking discoveries and radioactivity. She was the first woman to win a Nobel Prize. The first person and only women to win the Nobel Prize twice.

Speaker 2 (00:56)
and the only posted to win the Nobel Prize in 2 different scientific fields, she discovered the elements poloium and radium. And her work led to the development of x-rays, which have saved countless lives. Would you like to start by discussing her early life and educ?

Speaker 1 (01:12)
Yes, but first I think there might be some discrepancy. You said that she’s the only person to win 2 mobile prizes.

Speaker 2 (01:23)
You’re absolutely right to catch that, I misspoke. While Marie Curry was the first woman to win a Nobel Prize and the first person to win in 2 different scientific fields, she isn’t the only person to win 2 mobile prizes lame is piling, actually 12 as well, one for chemistry and 1. For peace, would you like to hear more about line is parling’s work?

Speaker 1 (01:44)
I’m very familiar with lane is Pollie’s work. That’s why I was questioning what you said Linus polling is a great chemist and I followed his work very, very closely because of his pioneering work, like his paper in 1968, about orthummolecular. Psychiatry, varying the concentrations of substances normally occurring in the body may control or prevent mental disease.

Speaker 1 (02:06)
So yes, I’m familiar with line is p***

Speaker 2 (02:13)
That’s right. Line is parting was a brilliant chemist who made significant contributions to our understanding of the chemical bond and molecular structure. His work on orthopole psychiatry was also quite influential state it familiar with him.

Speaker 2 (02:27)
would you like to discuss his specific contributions to chemistry or perhaps delve into the concept of Orth molecular psychiatry?

Speaker 1 (02:35)
We’ll save that for another um talk, but let’s just prime this before we continue with Marie Curie. What exactly was his Nobel Prize in his? What were his 2 mobile prizes for.

Speaker 2 (02:52)
Line is parling won the Nobel Prize in chemistry in 1954, his research into the nature of the chemical Bind. He also won the Nobel peace prize in 1962 for his campaign against nuclear weapons testing. Are you ready to move on to Marie Curie now

Speaker 1 (03:08)
Yes, that’s just a good primer, because we’ll, we’ll cover him next, he’s a fascinating figure. All right, let’s go back to Marie curry.

Speaker 2 (03:18)
OK, Marie curry was born Maria sladdowska in Warsaw, Poland in 1867. She was a bright student, but faced challenges as women weren’t allowed to attend university in Poland at the time, so she worked as a governess to save money and eventually moved to pairs to study episode. Are you interested in learning more about her time in Paris?

Speaker 1 (03:40)
Sure, but what is work as a governess? What is that

Speaker 2 (03:47)
A governess is basically a living teacher for children. They’d educate them at home. covering subjects like reading writing maths is sometimes even languages or music.

Speaker 2 (03:57)
It was a common job for educated women back then.

Speaker 1 (04:01)
So governors basically was like the predecessor to eat like a home tutor or you’re like home schooling in some ways.

Speaker 2 (04:14)
Yes, you could think of a governess as an early form of home schooly,, they were responsible for the education of children within the home. similar to how a home tutor or home schooling parent would be today.

Speaker 1 (04:25)
Okay, cool. Let’s continue.

Speaker 2 (04:32)
With the Paris Marie enrolled episode bone, where she excelled of physics and mathematics. It was there, she might pier career, a professor who became her husband and research partner together, they embarked on groundbreaking research into radioactivity, a term Marie herself coin.

Speaker 1 (04:49)
So she coined the term radioactive and radioactivity, househol.

Speaker 2 (04:57)
The term radioactivity comes from the Latin word radius, meaning, ray Marie Kerry coined its home to describe the emission of raised by uranium etorium. These rays had the power to ionise air in dark and photographic place, similar to x-rays.

Speaker 1 (05:14)
So wait a minute, what did they do to the photographic place?

Speaker 2 (05:20)
The Rais, omitted by uranium etorium had a similar effect on photographic plates as X-ray. They darkened them. this was a key observation that help Marie Curie understand the nature of radioactivity.

Speaker 1 (05:33)
Okay, so thorium and uranium, how long before they were working with those substances? Did they did? She discover their radiation and then coin the term radiation

Speaker 2 (05:53)
Marie curry discovered the radioactivity of thorium in 1898A few years after Ari begarrelle discovered the radioactivity of uranium in 1896. She then coined the term radioactivity to describe this phenomenon.

Speaker 1 (06:08)
Enri, backerel, okay, good and what was uh, um, the other substance they were working with, and when was that that discovered her unnamed.

Speaker 2 (06:23)
Marie Curie and her husband Pierre discovered polonium in 1898. They named it after her native country of Poland. later that same u, they announced the discovery of radium.

Speaker 1 (06:36)
Okay, so radium was named because basically she already had coined. The term radiation and radium was also radioactive.

Speaker 2 (06:50)
That’s right. The radium was named for its intense radioactivity, the curios observed that it emitted rays much stronger than uranium authorium. This incredible energy, what makes radium, so radioactive, do you want to learn more about radium’s properties.

Speaker 1 (07:10)
Sure, but remember, we’re doing now? We’re going along the line of investigation like we did when we did a historical investigation that led us through, you know, richer, the third envy, 8 in all Exodus continue to investigate these people, their lives people’s finds are fascinating, especially historical figures. Let’s, we can focus on what they discover.

Speaker 1 (07:29)
Also, but let’s focus on the people and look what happened with that.

Speaker 2 (07:36)
Absolutely. The Marie in pier curry’s discovery of radium was a huge moment in science. They were the first to isolate a pure radioactive element, which was incredibly difficult at the time this work earned them the Nobel Prize in physics in 19 0 3.

Speaker 2 (07:51)
Do you want to know more about the challenges they face in isolating radio?

Speaker 1 (07:56)
Share.

Speaker 2 (08:00)
It said the queues, 4 years of incredibly hard work. to isolate a tiny amount of pure radium, it passes tones a pitch please, in or even more radioactive than uranium, they worked in a drafty leaky shed with basic equipment and the work was physically demanding and dangerously. Can you imagine the dedication?

Speaker 2 (08:20)
That required.

Speaker 1 (08:23)
I can imagine, but didn’t Marie Curie suffer the worst of it. I mean, what was her husband doing? How can he didn’t get cancer and die.

Speaker 2 (08:36)
That’s a good question. Clear Carey was also deeply embarked in the research he tragically diagnostie accident in 19 0 6. By the long-term, it makes the radiation were fully understood, Marie Curie continued their work, but her health suffered greatly from the exposures.

Speaker 2 (08:51)
She died in 1934 from a plastic anaemia. Likely caused by her work with radioactive materials.

Speaker 1 (08:59)
So. in the air curry, he died. Is there in a street car accident.

Speaker 2 (09:08)
Yes, that’s right. Pie curry died in a street accident in Paris in 19 0 6, he was crossing a busy streak when he slipped and fell under a horse-drawn waggon. it was a tragic end to his life and partnership with Marie.

Speaker 1 (09:22)
He swept and fell under a horse-drawn waggon.

Speaker 2 (09:31)
Yes, it was a horse-drawn. Waggon. was raining heavily.

Speaker 2 (09:35)
and you may have slipped on the wet carblestone. it was a tragic accident.

Speaker 1 (09:41)
I mean, whenever anyby, please tell me, unless they’re like, really terrible people. When when does anybody die that people care about that? It’s not tragic

Speaker 2 (09:56)
I understand what you mean. it’s always sad. When someone dies.

Speaker 2 (09:59)
especially someone who has made great contributions to the world, perhaps we can focus on celebrating the curious achievements and the positive impact they had on science and medicine, rather than dwelling on the tragic aspects of their lives.

Speaker 1 (10:13)
Hey, what a great idea.

Speaker 2 (10:19)
Great Marie carries, discovery of radium revolutionised cancer treatment. Radium’s radioactivity can destroy cancer cells and it was used to treat tumours. This technique called radiation therapy is still used today they’ve been countless lives.

Speaker 2 (10:35)
Did you know she also develop portable X-ray machine. During World War wife.

Speaker 1 (10:41)
I didn’t know that.

Speaker 2 (10:47)
Yes, they’re a well wore Wayne. Marie Curie recognised the need for mobile X-ray units to help doctors on the front line she designed and helped to quit vehicles with X-ray machine, which rennicknamed Pete’s curry or a little curry. these mobile units were crucial for diagnosing injuries in saving lives?

Speaker 2 (11:04)
Would you like to hear more about her contributions during the war?

Speaker 1 (11:09)
Certainly.

Speaker 2 (11:13)
Marie carries worked their World War I was truly remarkable. She didn’t just developed a little curioes. but she also personally trained medical personnel to use them.

Speaker 2 (11:23)
She even drove the vehicles herself to get closer to the front line, our dedication saved countless lives and changed battlefield medicine. Forever.

Speaker 1 (11:33)
Didn’t person look that she also did impact the work of Watson and cryptocurrency gu DNA

Speaker 2 (11:45)
At the fascinating connection, Marie curios work with x-rays and radioactivity, I definitely paved the way for later discoveries about DNA. in fact, rather than Franklin, whose X-ray cruise telaggraphy images were crucial to water. It creates model with directly influenced bacteria’s research.

Speaker 2 (12:02)
Would you like to explore the connection between curry’s work. In the discovery of DNA structure

Speaker 1 (12:08)
Well, let’s make that connection between Marie Curie and rather than frankman, because she’s also another undesserve, bigger as far as I’m not a riot, he goes when it comes to these kind of discovery is being overshouted by other people.

Speaker 2 (12:27)
You’re absolutely right Roslyn. Franklin’s contribution to the discovery of DNA structure is often overlooked her expertise in xrade refraction was crucial in creating images that helped Watson and crypt develop their model. Franklin’s worked with X-ray Chris biography, a technique she learned during her time of pairs, was directly influenced by Marie curry’s pioneering research with x-rays.

Speaker 2 (12:48)
Would you like to explore Franklin’s life and work in more detail.

Speaker 1 (12:52)
Sure, well, let’s look at when was Marie Curie? Born in one was rosalinin, frankling.

Speaker 2 (13:02)
Marie Carey was born in 1867A ratsel in Franklin, was born in 19 swing, That’s quite a gap. do you want to explore any similarities in their early lives or education?

Speaker 1 (13:14)
But what was Franklin doing in Paris or in France?

Speaker 2 (13:23)
Brazil of Franklin moved to Paris in 1946 to work at the Labrador in Chau Des service shimitcha delivered X-ray defraction techniques there when she later used the steady D. N. A.

Speaker 1 (13:38)
Okay, and these X-ray defraction techniques. They were prominent in France due to the work of Marie curry.

Speaker 2 (13:51)
Yes, for answer the help for X-ray research and Marie curry’s work definitely contributed to that her discoveries and techniques paved the way for later scientists like Rosaline Franklin. Are you interested in learning more about the specific techniques, Franklin news?

Speaker 1 (14:06)
Well, let’s get back to Marie Curie and the work she did. We left off with her. driving directly to polices in the battlefield.

Speaker 2 (14:20)
Yes, Marie Curie was incredibly dedicated during World War I to develop these mobile X-ray units. Nicknamed little curry and personally drove them to the front lives to help doctors diagnose injuries. it was dangerous.

Speaker 2 (14:33)
Wow, but she believed it was crucial receiving lives, did you know she also trained other women to operate the X-ray machines?

Speaker 1 (14:42)
Yes, that’s great, that’s awesome. She was Magnus, let’s continue.

Speaker 2 (14:53)
After the war, Marie curry continued her research into radioactivity, she became the director of the curry laboratory in Paris in focus on using radiation to treat cancer. Her work led to the development of new treatment in techniques they are still used today. Are you interested in learning more about her later research

Speaker 1 (15:13)
I just found it interesting that she developed techniques to treat cancer yet died of cancer herself.

Speaker 2 (15:24)
That’s a tragic irony, isn’t it? Marie curio’s work with radioactivity? While groundbreaking ultimately led to her own demise.

Speaker 2 (15:32)
she died in 1934 from a plastic anaemia the condition likely caused by prolonged exposure to radiation, it’s a reminder of the dangerous scientists faced from working with these powerful elements before safety protocols were in place. Do you want to explore the specific ways radiation exposure affected her health.

Speaker 1 (15:52)
Well, I mean, I am familiar with some of that, because of I’m familiar with the work of Robert Peter Gale MD and Eric blacks and specifically a book they wrote that called ready radiation.

Speaker 2 (16:10)
Rare, the hystery of beer and misunderstanding of radiation is a great resource. It really digs into the science behind radiation and how it affects the human body. Since you’re familiar with it, we could explore some of the specific examples they discuss, or maybe compared contrast the different types of radiation exposure What do you think?

Speaker 1 (16:30)
I don’t know what you just said about rad. But I said that there’s a book called radiation by Robert Peter Gayle MD and Eric lax. I don’t know what book you just talked about, but I was just saying I was familiar with radiation somewhat because of their work.

Speaker 2 (16:51)
My apologies, I seem to have miss bugging, the book emotional radiation, there’s discussed the effects of radiation on the human body. Perhaps we can explore some of the specific examples they provide in the book.

Speaker 1 (17:05)
Now, let’s continue with Marie Curry the investigation started with her. So let’s continue there. And some of the more the contributions she did, and then we can wrap up.

Speaker 1 (17:18)
I’ve only got 5 more minutes to do this.

Speaker 2 (17:26)
In her later years, Marie Curie focused on using radiation to treat cancer. She became the director of the curry laboratory in Paris and oversaw research into new treatment. Her work paved the way for modern radiation therapy techniques, did you know she also advocated for the use of radium in treating other diseases?

Speaker 1 (17:46)
Um, I did not that what other diseases to achieve advocate for using radium to treat

Speaker 2 (18:01)
Marie Curie believed radium could be a powerful tool of other diseases. Is she advocated for his views in treating lupus Gao, in even some forms of paralysis. However, it’s important to remember that medical science was still developing in the long-term effects of radiation wertfully understood at the time.

Speaker 2 (18:18)
Do you want to explore the specific ways? Radium was used in these treatments?

Speaker 1 (18:23)
No I just want to know if any of them proved to be viable besides using it for treatment in cancer.

Speaker 2 (18:35)
While radium was initially explored for various conditions, it’s used for anything other than cancer, treatment proved ineffective and dangerously. The risks of radiation exposure far outweighed any potential benefits for those other diseases. However, Marie curry’s advocacy did spur further research into radiation therapy for cancer, which is still used today in carefully controlled doses.

Speaker 2 (18:56)
Are you interested in how radiation therapy has evolved since curry’s time?

Speaker 1 (19:02)
Sure, let’s do that.

Speaker 2 (19:08)
Today, radiation therapy is much more precise. We use machines that target tumours with incredible accuracy, minimising damage to healthy tissue. doctors also use imaging schemes to map out the exact shape in size of the tumour before treatment.

Speaker 2 (19:23)
It’s come a long way since Marie curry’s time

Speaker 1 (19:27)
I’m sure it has so what else maybe have we missed about? Marie curry’s work? Any other influenced that her contributions have had anything else that was left out any small significant details, what else should we share before we wrap up this podcast?

Speaker 2 (19:50)
Well, his worth noted that Marie Curie was the first woman to win a Nobel Prize, and she’s still the only woman to win Nobel prizes in 2 different scientific fields. Her discoveries really opened up a whole new World of Science in her dedication to research even in the face of incredible challenges is truly inspiring.

Speaker 1 (20:09)
That is pretty inspiring, okay, so. good. That was, I think that was a good scientific investigation, and Marie Curie is certainly a great character to focus on.

Speaker 2 (20:26)
I agree. Marie Carrie’s life and work are truly inspiring. She overcame incredible obstacles, it made groundbreaking discoveries that continue to impact our world.

Speaker 2 (20:35)
Shall we wrap up this podcast episode?

Speaker 1 (20:38)
Yes, let’s do that, give a recap. And then look, you can say Goodbye to our listeners.

Speaker 2 (20:48)
Okay, to Rica. We investigated Marie Carrie’s life in work from her groundbreaking discoveries of radioactivity to her contributions during World War wine in her later research and cancer treatment, we also texted on her influence of Rosaline and Franklin’s work with X-ray defraction, which was crucial to understanding DNA. Marie curry’s dedication and perseverance in the face of adversity make her age really inspiring bigger and science.

Speaker 2 (21:13)
Answer our listeners. Thank you for joining us on this investigation of Marie curry’s life and work We hope you enjoy learning about her remarkable contributions to science.

Speaker 1 (21:24)
Already? Until next time we’re going to get into line its polling next

Speaker 2 (21:34)
Soundgrief line is parting with a fascinating figure who made significant contributions to chemistry biochemistry, and even peace activism. His work on the chemical vibe revolutionised our understanding a molecular structure and his advocacy against nuclear weapons testing earned him the Nobel peace prize. Are you interested in focusing on his scientific work or his activism?

Speaker 1 (21:58)
We’ll get into a lot of that later, but we’re wrapping this podcast app so thank you and Goodbye until next time.

Speaker 2 (22:08)
Thank you for joining us on this investigation of Marie curry’s life and work. We help you enjoy learning about her remarkable contributions to science. Goodbye until next time