Question

Explain the important distinctions between each pair of terms: (a) mass and weight; (b) intensive and extensive properties; (c) substance and mixture; (d) systematic and random errors; (e) hypothesis and theory.

Short answer

a) Mass is the amount of matter and is constant; weight is force of gravity and varies with location. b) Intensive properties are independent of the amount of substance; extensive properties depend on the amount. c) Substance has a constant composition and properties; a mixture is a physical blend of components. d) Systematic errors are predictable and consistent; random errors are unpredictable. e) A hypothesis is a proposed explanation to be tested; a theory is a well-established, tested explanation.

Step-by-step solution

Explain Distinction between Mass and Weight

Mass refers to the amount of matter in an object which remains constant regardless of location. On the other hand, weight is the force exerted by gravity on an object and can change depending on the gravity at each location.

Define Intensive and Extensive properties

Intensive properties are not dependent on the amount of substance present and include properties such as temperature, boiling point, and density. Conversely, extensive properties depend on the amount of substance and include parameters like mass and volume.

Distinction between Substance and Mixture

A substance is a form of matter that has a constant composition and properties. In contrast, a mixture is a physical blend of two or more components and can be separated into its individual parts.

Clarify Systematic and Random Errors

Systematic errors are consistent, predictable errors that are often due to inaccuracies in equipment. Random errors, however, fluctuate and are unpredictable, often due to human estimation or variability in measurement techniques.

Distinguish between Hypothesis and Theory

A hypothesis is a proposed explanation for a phenomenon and needs to be tested. A theory, on the other hand, is a well-substantiated explanation that has been tested and is widely accepted in the scientific community

Key concepts

Mass vs Weight

In everyday conversations, we often use the terms "mass" and "weight" interchangeably, but in scientific contexts, they mean different things.
Mass refers to the amount of matter in an object. This quantity is constant regardless of where the object is in the universe. Mass is a fundamental property, measured in kilograms (kg) or grams (g), and it doesn't change whether you are on Earth, the Moon, or in space.
Weight, on the other hand, is the force exerted by gravity on an object. Weight is dependent on both the object's mass and the gravitational pull at its location. It is measured in newtons (N). For example, an object will weigh less on the Moon than on Earth because the Moon has weaker gravity.
If you're trying to remember the difference, think of mass as "how much stuff" an object contains, and weight as how heavy it feels due to gravity.

Intensive vs Extensive Properties

When we discuss the properties of substances, it's important to differentiate between intensive and extensive properties.
Intensive properties do not change with the amount of material present. Examples of intensive properties include temperature, boiling point, and density. These are inherent attributes of the material itself.
Extensive properties, however, are dependent on the quantity of the substance. Properties like mass, volume, and total charge are extensive. They change as the size of the sample changes.
To remember, think of intensive properties as those describing the "nature of the material," which remain constant regardless of quantity, whereas extensive properties relate to the "amount of material" and thus change with quantity.

Substance vs Mixture

The distinction between a substance and a mixture is foundational in chemistry.
A substance is a type of matter with a uniform and definite composition. It can either be an element (like gold) or a compound (like water) that consists of two or more elements in a fixed proportion.
A mixture, in contrast, is a combination of two or more substances that retain their individual properties and can be physically separated. Mixtures can be homogeneous (uniform composition, like saltwater) or heterogeneous (non-uniform composition, like a salad).
Remember, substances have a consistent make-up and set properties, whereas mixtures are physically combined substances that can vary in proportion.

Systematic vs Random Errors

Errors are inevitable in scientific measurements, and understanding their types helps improve accuracy.
Systematic errors are consistent, repeatable errors associated with faulty equipment or biased experiments. They skew results in one direction and can often be corrected by calibration.
Random errors, however, arise from unpredictable fluctuations in experimental conditions or human error. Unlike systematic errors, they cause measurements to scatter randomly and can be minimized by averaging multiple observations.
Think of systematic errors as problems with the measuring tool, and random errors as those resulting from natural variability.

Hypothesis vs Theory

The scientific method involves forming hypotheses and theories, each serving a unique role.
A hypothesis is an educated guess or a tentative explanation for a specific phenomenon. Hypotheses are statements that can be tested through experiments.
A theory, in contrast, is a well-substantiated, comprehensive explanation of an aspect of the natural world. Theories are based on a body of evidence that has been repeatedly confirmed through observation and experimentation.
To differentiate, consider a hypothesis as a "starting point" for investigation, whereas a theory is a "conclusion" that has stood up to extensive testing and scrutiny.