Everything Everywhere Daily: History, Science, Geography & More - The Scientific Method
Episode Date: March 29, 2025The modern world is built on science. Today, millions of scientists all over the world are doing research in thousands of different fields and specializations. All of these researchers are, to some... degree, using a system that was developed over the course of centuries. A methodology that allows for the discovery of scientific truth. It isn’t perfect, but it ushered in a scientific revolution and helped create the modern world we live in. Learn more about the scientific method, what it is, and how it developed in this episode of Everything Everywhere Daily. Sponsors Mint Mobile Cut your wireless bill to 15 bucks a month at mintmobile.com/eed Quince Go to quince.com/daily for 365-day returns, plus free shipping on your order! Stitch Fix Go to stitchfix.com/everywhere to have a stylist help you look your best Tourist Office of Spain Plan your next adventure at Spain.info Stash Go to get.stash.com/EVERYTHING to see how you can receive $25 towards your first stock purchase and to view important disclosures. Subscribe to the podcast! https://everything-everywhere.com/everything-everywhere-daily-podcast/ -------------------------------- Executive Producer: Charles Daniel Associate Producers: Austin Oetken & Cameron Kieffer Become a supporter on Patreon: https://www.patreon.com/everythingeverywhere Update your podcast app at newpodcastapps.com Discord Server: https://discord.gg/UkRUJFh Instagram: https://www.instagram.com/everythingeverywhere/ Facebook Group: https://www.facebook.com/groups/everythingeverywheredaily Twitter: https://twitter.com/everywheretrip Website: https://everything-everywhere.com/ Learn more about your ad choices. Visit megaphone.fm/adchoices
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The modern world is built on science.
Today, there are millions of scientists all over the world doing research in thousands of
different fields and specializations.
All of these researchers are, to some degree, using a system that was developed over the
course of centuries, a methodology that allows for the discovery of scientific truth.
It isn't perfect, but it ushered in a scientific revolution and helped create the modern
world that we live in today.
Learn more about the scientific method, what it is, and how it developed.
on this episode of Everything Everywhere Daily.
What if your perceptions about the past were wrong?
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The scientific method is one of humanity's greatest achievement.
yet it really isn't an invention, nor is it a discovery.
The scientific method is a systematic approach to understanding the natural world
through observation, hypothesis formation, experimentation, and analysis.
It represents humanity's most powerful tool for gathering reliable knowledge about the universe,
allowing us to move beyond speculation and develop evidence-based understanding.
The scientific method isn't perfect, and it doesn't work in every situation.
more on that in a bit, but it is the best framework we have for determining the truth of things
in the natural world.
Depending on what source you use, you will see five, six, or maybe even seven steps in the
scientific method.
All of the various ways of describing the scientific method are pretty much the same,
with some steps combined or some extra ones added.
For the purpose of this episode, the steps in the scientific method are,
observation, questioning, hypothesis building, experimentation, analysis, and conclusion.
To illustrate how it works, I'll use one of the most famous cases ever, Alexander Fleming's
discovery of penicillin. In 1928, Fleming was studying the Staphylococcus bacteria which
causes infections, and one day he noticed something unusual. A mold, later identified as
penicillum notatum, had accidentally contaminated one of the first.
of his petri dishes, and the bacteria around it had been killed. This was the first step in the
scientific method, observation. Fleming had to actually take notice of what happened. And that
sounds trivial, but there are countless things that can easily be overlooked. In Fleming's case,
perhaps the absence of bacterial growth is pretty obvious, but it isn't always so depending on what
it is you're doing. The second step is also pretty simple. Fleming had to ask himself,
Why? Why did the bacteria die around the mold? Maybe when the mold contaminated the sample,
it was at a different temperature. Or maybe it had been contaminated by an outside chemical,
and it wasn't the mold itself that killed the bacteria. Once the question was asked,
it was necessary to come up with a hypothesis. While all the things I just mentioned could have
been true, it wasn't the most obvious reason. The hypothesis that Fleming proposed was that there
was something in the mold that killed off the bacteria. The next step was to test the hypothesis
with an experiment. To test his experiment that the mold produced a substance capable of killing
bacteria, Alexander Fleming conducted a series of experiments in which he isolated the mold
from the contaminated petri dish and allowed it to grow in a controlled environment. He then collected
the fluid surrounding the mold, not the mold itself, which he suspected contained the antibacterial
substance. Fleming applied this mold extract to cultures of various harmful bacteria,
including Staphylococcus, and observed that the bacteria were inhibited or destroyed in the
areas where the extract was present. He also tested the substance with other cells, such as animal
cells, and found that it didn't harm these cells. The next step was compiling and analyzing the
data he collected from his experiment. Having gone through the data, he reached the final step
and made a conclusion. There was something in the mold that killed the bacteria.
These results confirmed his hypothesis that the mold secreted a powerful antibacterial agent,
and he called it penicillin.
This process sounds pretty simple and common sense, yet it was something that took centuries to develop.
Ancient people did have systemized ways of learning.
Ancient China and India contributed to the development of the scientific method
through their emphasis on observation, practical experimentation, and logical reasoning.
In China, advancements in fields like medicine, astronomy, and engineering were driven by careful
empirical study and innovation, such as detailed records of celestial events and the invention
of tools like the compass and the seismograph. Similarly, ancient Indian scholars made major
contributions in mathematics, astronomy, and medicine using systematic observations, classification,
and logical analysis. Likewise, the Babylon.
and Egyptian civilizations practice empirical observation for practical tasks like medicine and astronomy,
but without any formal methodology.
Early ancient civilizations, like India, China, Babylon, and Egypt, were not practicing
the scientific method as we know it today, because their approaches to understanding the world
were largely based on practical experience, tradition, and spiritual or religious beliefs,
rather than systematic experimentation and hypothesis testing.
While they made significant observations and developed advanced technologies,
their methods lacked the structured process of forming testable hypotheses,
conducting controlled experiments, and analyzing results objectively.
Knowledge was often passed down through authoritative texts or oral traditions,
and the explanations for natural phenomenon were frequently tied to mythology or divine influence.
The ancient civilization that saw major advances towards developing the scientific method was the Greeks.
The ancient Greeks made significant advancements towards the development of the scientific method
by shifting the focus of inquiry from mythological explanations to rational thought and natural causes.
Philosophers like Thales and Axidimander began to propose that natural phenomenon
could be explained by underlying principles rather than the actions of the gods.
Pythagoras introduced the idea that mathematics could reveal truth about the universe,
laying the groundwork for scientific reasoning.
Plato emphasized deductive reasoning and abstract ideals,
although he devalued sensory experience,
while his student Aristotle took a more empirical approach,
advocating for careful observation, classification, and logical reasoning.
Aristotle's method of systematic inquiry, an emphasis on cause-and-effect relationships,
brought science closer to a structured method of investigation,
even if it still lacked experimentation in the modern sense.
Overall, the Greeks contributed foundational ideas about logic, evidence,
and the pursuit of knowledge through reason,
core elements that would later evolve into the scientific method.
Now, in most episodes, when I'm talking about the development of something,
I usually talk about the Romans after I talk about the Greeks.
However, in this case, the Romans did absolutely nothing in this department.
The group that really took up the mantle of the Greeks
were the Muslim scholars during the Islamic Golden Age.
During the Islamic Golden Age,
Muslim scholars made crucial advancements
towards the development of the scientific method
by emphasizing observation,
experimentation, and critical thinking in their pursuit of knowledge.
Building on the works of the Greeks and other ancient civilizations,
they translated and preserved classic texts
while also improving and challenging them
through original research.
Scholars like Ibn El Hitham played a pivotal role in shaping experimental science.
In his book, The Book of Optics, he outlined a systematic approach that involved observation,
forming hypotheses, testing through controlled experiments, and drawing conclusions,
very closely resembling the modern scientific method.
Muslim thinkers also stressed the importance of skepticism and verification,
insisting that conclusions should be based on evidence rather than tradition or authority.
fields such as medicine, astronomy, chemistry, and mathematics,
flourished as scholars conducted detailed experiments,
recorded their findings meticulously,
and developed theories grounded in empirical observation.
Their approach marked a shift from purely philosophical reasoning like the Greeks
to a methodical evidence-based investigation of the natural world.
During the same period in Europe,
scholars such as Roger Bacon emphasized the importance of empirical observation and experience,
experimentation, arguing that knowledge should be derived from experience rather than solely from
accepted authorities. Universities emerged as centers of learning where logic and debate were
practiced, helping to refine methods of reasoning and analysis. While experimentation was still
limited and often intertwined with religious beliefs, the period saw a growing emphasis on
critical thinking, systematic observation, and the questioning of established ideas.
During the scientific revolution which spanned the 16th to 17th centuries,
the scientific method underwent a major transformation as thinkers began to reject
reliance on tradition and authority in favor of direct observation, experimentation,
and logical reasoning.
Francis Bacon promoted inductive reasoning, encouraging science to gather data through careful
observation and then building general theories from specific facts.
René Descartes, on the other hand, emphasize de Inductive reasoning,
and mathematical logic as a path to certain knowledge.
Moving into the 19th and 20th centuries,
some philosophers of science began to think about the scientific method
much more explicitly.
Carl Popper and Thomas Coon made influential contributions
to the philosophy of science
by offering different perspectives
on how scientific knowledge progresses
and how the scientific method operates.
Carl Popper emphasized the importance of falsifiability.
the idea that for a theory to be scientific, it must be testable and able to be proven wrong.
He argued that science advances not by confirming hypotheses per se, but by rigorously attempting
to refute them. According to Popper, a good scientific theory makes bold predictions
and stands up to repeated attempts at falsification, which strengthens its credibility.
In contrast, Thomas Coon introduced the concept of paradigm shifts in his work of the structure
of scientific revolutions.
He argued that science does not progress in a steady, cumulative way, but rather through periods
of normal science, followed by revolutionary changes.
During normal science, researchers work within an accepted framework or paradigm.
When enough anomalies built up that the current paradigm can't explain something,
a scientific revolution occurs and a new paradigm replaces the old one.
Kuhn's view challenged the idea of linear scientific progress and highlighted the role of
social and historical context in shaping scientific discovery.
Together, Popper and Kuhn expanded our understanding of how science works,
not just through experiments and data, but through philosophical and cultural processes as well.
Now, earlier in the episode, I mentioned that you can't always use the textbook version of
the scientific method that I gave.
And now you might be wondering, well, why not?
Well, it has to do with the ability to do experiments.
In fields like astronomy, you can't really do experiments.
You can make observations and create hypotheses,
but it is impossible to conduct experiments most of the time.
For example, if you have a hypothesis on the formation of galaxies,
you can't go and make a galaxy to test your hypothesis.
The only thing you can do is make more observations
to see if they fit your hypothesis
or to see if they falsify your hypothesis.
The reason why astronomers want bigger and bigger telescopes is that they want to push the limit
of what type of observations are possible.
Sometimes experiments aren't possible due to ethics, budget, or logistics.
When evidence is gathered in the field of nutrition, for example, there usually aren't
controlled experiments that are conducted, although sometimes are.
They usually conduct epidemiological studies, where they survey a large number of people.
The problem with these studies is that they rely on statistics to
lean information out of the data, and at that point your conclusion will rest on what statistical
analysis you run and how you interpret it. Another item that's often added as a requirement to the
scientific method is replicability. It isn't enough for one scientist to conduct an experiment.
It's necessary for everyone to be able to repeat the same experiment and get the same results.
This has been a huge problem in many fields, particularly in fields that's
study humans, such as psychology and medicine, where many studies simply cannot be replicated
by anyone else. Most people think that when a research paper is submitted to a journal, the process
of peer review checks to see if an experiment works. And that is not at all what peer review does.
In some fields, the inability to replicate experiments has been dubbed the replication crisis.
Problems with peer review, academic publishing, and the replication crisis will be addressed
in future episodes.
The scientific method isn't a hyper-strict checklist that is followed on every single
scientific inquiry.
Rather, it's more of a way of thinking that allows you to approach scientific inquiry
in such a way as to increase the odds that when you find something to be true,
it is in fact actually true.
The executive producer of Everything Everywhere Daily is Charles Daniel.
The associate producers are Austin Oakden and Cameron Kiefer.
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