Theory Of Knowledge_ Natural Sciences Chapter Notes PDF

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This document provides chapter notes on natural sciences from a Theory of Knowledge perspective. It encompasses basic terminology, defining science, discussing scientific knowledge, and examining related concepts.

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Basic Terminology
Term Definition

Section 1 Defining Science and Its Boundaries

Science The term "science" originates from the Latin scientia meaning knowledge.

Science not only encompasses specific disciplines (e.g., biology, chemistry,
physics) but also the broader methodology used to acquire knowledge
systematically.

is both knowledge and the method for obtaining knowledge

Purpose Of Science Science aims to describe, explain, predict, and often manipulate natural
phenomena through observation, experimentation, and logical reasoning

Boundaries and The boundaries of natural science can be blurry, intersecting with human
Blurriness Of Science sciences and cultural studies.

For instance, modern physics and psychology touch on questions of human
perception and cognition, once solely in the realm of philosophy.

Karl Popper's Popper argued that scientific theories must be falsifiable.
Falsification Principle

Verificationism Principle where theories are considered valid if confirmed through repeated
observations.

Pseudo-science Claims that are non-falsifiable fall under pseudo-science.

For example, astrology is often cited as pseudoscience because its predictions
are not reliably testable. In practice, we find that astrologers will latch onto
even the weakest sorts of evidence in order to support their claims; however,
their repeated failures to find evidence are never allowed as evidence against
their theories.

Section 2 Perspectives on Science and Knowledge

Francis Bacon Bacon advocated for empiricism.
viewed science as a powerful tool to control and manipulate nature,
uncovering hidden truths.

Empiricism the view that knowledge comes only from sensory experience and experiment

Structure of Scientific Book by Thomas Kuhn
Revolutions

Thomas Kuhn’s Theory introduced the idea of paradigm shifts
 Theory which suggests that scientific progress happens not linearly but
through cycles of "normal science" interrupted by revolutions.

Paradigm Shift Occurs when anomalies accumulate, causing a crisis in the current paradigm and
leading to a new framework.

Examples of Paradigm Copernican Revolution: Shifted from an Earth-centered to a heliocentric
Shifts model.

Newton’s Laws of Motion: Replaced earlier Aristotelian physics.

Darwin's Evolutionary Theory: Revolutionized biological sciences.

Quantum Mechanics and Relativity: Overturned the Newtonian framework
in physics.

The impact of Kuhn’s Kuhn suggested that science is less objective than believed because
theory in regards to paradigms depend on community consensus, and scientists’ acceptance of
objectivity theories

Science may be influenced by social or personal factors

Scientific Consensus Once a scientific claim is established as fact, it’s often treated as
unquestionable.

Controversies force the scientific community to re-examine established
“truths,” but consensus eventually closes the debate again.

The “Black Box” Over time, scientific processes that establish facts become “black-boxed,”
Phenomenon meaning they are no longer questioned or examined unless disrupted by a
significant anomaly.

Black Box Metaphor
Initially, new discoveries are rigorously examined, but once consensus is
reached, the processes that validated these facts fade into the background, like
contents hidden in a "black box." This allows for efficient progress, as not
everyone needs to understand every detail. However, it can also lead to a loss
of transparency, as the origins of accepted knowledge become obscure. If new
evidence challenges these "black-boxed" facts, scientists may reopen the
black box, re-evaluating and potentially revising what was once taken for
granted.

Section 3 Disseminating Scientific Knowledge

Role of Journals Academic journals are the primary medium for sharing scientific knowledge.
Articles must be peer-reviewed, allowing replication and verification by other
scientists, thus ensuring accountability.

Challenges in Scientific Access and Cost: Paywalls limit accessibility for non-experts or researchers
Publishing without institutional support.
 Publish-or-Perish Pressure: Scientists are pressured to publish frequently,
which can affect the quality or integrity of their work.

Jargon and Accessibility: Scientific language can alienate the general
public, contributing to distrust or misunderstanding.

Idealized vs. Realistic Popular science outlets often idealize the scientific process, whereas real
Portrayal science involves uncertainties and disagreements, which can erode public
trust.

Post-Truth World Impact Public skepticism toward scientific experts has grown, as observed in the
context of climate change and vaccine hesitancy.

Section 4 Methods and Tools of Science

Nature of Observation Observation is often thought of as passive, while experimentation is active.

Both are essential to the scientific method, and observation can introduce
subjective biases.

Controlled Experiments Scientists attempt to isolate and manipulate variables to understand natural
phenomena, often using artificial conditions, which raises questions about
whether these findings truly represent nature.

Survivorship Bias Famous successes in science overshadow failures, potentially distorting the
historical record of scientific progress.

Scientific Objectivity Objectivity aims to eliminate personal biases, achieved by standardizing
methods, tools, and units.

For example, photographs are often used over illustrations to minimize
subjective interpretation.

Is True Objectivity The scientific ideal assumes that observers are interchangeable, yet human
Possible? limitations suggest that complete objectivity may be unattainable.

Reductionism Analyzing complex phenomena by breaking them down into simpler
components, like genes in biology or atoms in chemistry.

Limitations of Pure reductionism may overlook how interconnected systems function as a
reductionism whole. Some phenomena, like ecosystems, cannot be fully understood solely
through their parts.

Emergence Higher-order simplicity or behaviors emerge from complex interactions.

Examples include ecosystems or brain functions, where collective
interactions reveal properties not present in individual components.

Section 5 Ethical Issues in Science
Ethics & Community Good science requires adherence to ethical standards, such as honest data
Standards reporting, transparency, and accountability through peer review.

Ethics of Misconduct Scientific fraud (e.g., falsifying data) undermines credibility, yet issues like
misconduct are still present, often driven by funding pressures.

Ethics in Application of Atomic Bomb Example: The Manhattan Project’s development of nuclear
Scientific Knowledge weapons raises ethical questions about the responsibilities of scientists and
the potential for destructive use.

Genetic Engineering: Innovations like gene editing bring ethical concerns
regarding unintended consequences, biodiversity, and social implications.

Cost-Benefit Analysis in Cost-benefit analysis is used in decision-making, aiming to balance
Science advantages against potential harms.

High-level policymakers often use it, but its effectiveness is limited when
unknowns are present or when it depends heavily on expert judgment.

Risks and Criticisms Blind acceptance of these analyses may obscure critical perspectives, while
automatic distrust may disregard valuable expertise.

Feminist and Postcolonial Exclusion in Science: Historically, science has marginalized certain groups
Critiques based on gender, race, and sociopolitical status. Feminist and post-colonial
scholars critique how scientific knowledge has traditionally excluded
Indigenous and non-Western perspectives.

Masculine Worldview: Science has often been shaped by masculine values,
impacting areas like experimental focus and career access for women.

Examples of Bias: Cases like Rosalind Franklin’s contributions to DNA
structure research illustrate gender biases within scientific communities.

Case Studies
Copernican Nicolaus Copernicus proposed that the Earth and other planets revolve around the
Revolution Sun, challenging the long-accepted geocentric model that placed Earth at the
(Heliocentric Model) universe’s center.

This idea, further supported by astronomers like Galileo and Kepler, shifted the
way humanity viewed its place in the cosmos and set the stage for modern
astronomy.

The Copernican model eventually gained acceptance, drastically altering
perspectives on both science and religion, as it contradicted theological views of
the time.
 This shift is considered one of the first major paradigm shifts, demonstrating how
new evidence can fundamentally reshape understanding.

Newton’s laws of Isaac Newton’s laws of motion and universal gravitation provided a
motion comprehensive explanation for both terrestrial and celestial phenomena, replacing
Aristotelian physics.

Newton’s theories established a mechanical universe governed by predictable,
mathematical laws.

Newtonian physics not only influenced science but also inspired other disciplines
by demonstrating that natural laws could be discovered and understood through
observation and reasoning.

It remained the dominant paradigm until the 20th century when Einstein’s
theories introduced new concepts of relativity and challenged classical mechanics
on a fundamental level

Darwin’s theory of argued that species evolve over time through the survival and reproduction of
evolution by natural those best suited to their environment.
selection
This challenged the view that species were unchanging and introduced a dynamic
view of life.

Darwin’s theory transformed biology, providing a unifying explanation for the
diversity of life.

It also sparked intense debate, particularly concerning its implications for human
origins, and led to ongoing discussions in fields such as genetics and ecology.

Quantum Mechanics Quantum mechanics emerged in the early 20th century as scientists like Max
Planck, Niels Bohr, and Albert Einstein sought to explain phenomena that
Newtonian physics couldn’t, such as the behavior of particles at atomic and
subatomic scales.

The theory introduced concepts like wave-particle duality and uncertainty,
fundamentally altering our understanding of matter and energy.

This case study shows a shift from deterministic laws to probabilistic models,
with quantum mechanics revealing a more complex, less predictable universe at
the smallest scales.

This paradigm shift has led to advanced technologies like semiconductors and
quantum computing

Germ Theory developed in part by scientists such as Louis Pasteur and Robert Koch, proposed
that microorganisms are the cause of many diseases.

This concept replaced miasma theory, which suggested that diseases were spread
by "bad air."
 Germ theory revolutionized medicine, leading to sterilization, vaccination, and
antibiotics.

It fundamentally changed public health practices and improved life expectancy
worldwide. The shift highlights how scientific breakthroughs can directly impact
societal well-being.

Women and Figures like Rosalind Franklin, who contributed to discovering DNA’s structure,
Minorities in Science exemplify how women’s achievements have sometimes been overlooked in favor
of their male counterparts.

Feminist and post-colonial perspectives question whether traditional scientific
methods unintentionally favor certain worldviews, potentially limiting the
diversity of scientific inquiry. The study also considers curriculum and societal
influences that can restrict women’s access to scientific careers, highlighting
ongoing gender and racial gaps in scientific leadership​