Introduction to Science

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Presentation transcript:

Introduction to Science Physical Science Introduction to Science

Methods of Science The common steps that all scientists use to investigate a problem and design an experiment is called the SCIENTIFIC METHOD.

1. Choose A Problem The first step of the Scientific Method is to CHOOSE A PROBLEM; this often takes the form of a question. Example: What effect does caffeine have on the growth of a plant? ? Caffeine Arabidopsis

2. Research Your Problem Before continuing with the experiment a scientist should RESEARCH THE PROBLEM Ways to research: Make and record observations Talk to experts Go to the library or browse the internet

3. Develop A Hypothesis A HYPOTHESIS is a prediction that can be formally tested; it is based on your observations and research. An educated guess about what will happen Example: Caffeine will cause an increase in the growth of the plant.

4. Design An Experiment An EXPERIMENT is an investigation that tests a hypothesis by collecting data under controlled conditions. A controlled experiment often has 2 groups: The CONTROL group and the EXPERIMENTAL group CONTROL Group EXPERIMENTAL Group (nothing changed) (one variable changed) VS. NO caffeine WITH caffeine

Independent Variable The ONE thing that is CHANGED in an experiment is called the INDEPENDENT VARIABLE E.g. Independent variable is the amount of caffeine added to the plants Caffeine Independent Variable

Dependent Variable The DEPENDENT VARIABLE is the MEASURED result caused by the independent variable. The dependent variable DEPENDS on the independent variable E.g. The dependent variable is the measured growth of the plants

5. Test Your Hypothesis In order to TEST YOUR HYPOTHESIS the experiment that was designed must now be conducted. E.g. Allow both the control group and experimental groups of Arabidopsis plants to grow for a period of 5 days and record the height of every plant each day in a data table Day 1 Day 2 Day 3 Day 4 Day 5 Caffeine 1.4in 2.2in 3.9in 5.0in 8.5in Control 1.2in 1.9in 2.7in 4.1in 6.5in

6. Organize Your Data DATA is defined as any information that is obtained from an investigation The DATA that has been collected must then be ORGANIZED Usually the DATA will be put into a chart or graph to provide visual results that can be more easily interpreted

Effects of Caffeine on Arabidopsis Plant Growth

7. Draw Conclusions The data that has been collected in the experiment must then be ANALYZED and the scientist must come to a CONCLUSION The CONCLUSION must indicate whether the hypothesis was accepted or rejected E.g. Looking at the data, the hypothesis that caffeine will increase Arabidopsis growth is confirmed

Draw Conclusions Once a conclusion has been drawn a scientist will then PUBLISH the results to share with other scientists Other scientists can try to replicate the results by repeating the same procedure

Hypothesis Becomes A Theory A hypothesis that is supported many different times by many different scientists will become a THEORY A THEORY is NOT a guess!! A THEORY is CONFIRMED by scientific observations. E.g. Theory of Gravity, Atomic Theory, Theory of Evolution

END OF SCIENTIFIC METHOD NOTES

International System of Measurement (SI) All scientists use the same system of measurement called the INTERNATIONAL SYSTEM OF MEASUREMENT (SI). Meter (length) Gram (mass) Liter (volume) Second (time) Celsius degree (temperature) Scientists around the world communicate quantitative data using the SI system

Science Skills The Big Ideas of Physical Science Matter Sub Atomic, Atomic, Molecular, Dark Matter Newtonian Physics Force and Motion Space / Time Relativity Energy Potential, Kinetic, Chemical, Nuclear, etc…

Science Skills Scientific Notation Writing REALLY BIG or really small numbers easily

Science Skills Scientific Notation Always Have ONLY ONE Number to the Left of the Decimal Point

Le Système International d’Unités Science Skills Le Système International d’Unités SI Units Universally Used by Scientists With exceptions British Engineering Foot, slug, BTU 

Science Skills SI Units (Base) Length – meter (m) Mass – kilogram (kg) Time – second (s) Temperature – Kelvin (K) Amount – mole (mol)

Science Skills SI Units (Derived) Area – square meter (m2) Volume – cubic meter (m3) Density* – kilogram/cubic meter (kg/m3) Pressure – Pascal kg/m*s2 (Pa) Energy – Joule kg*m2/s2 (J)

Science Skills Greek Prefixes Multipliers of SI Units Giga G 109 1,000,000,000 Mega M 106 1,000,000 Kilo k 103 1,000 Centi c 10-2 0.01 Milli m 10-3 0.001 Micro m 10-6 0.000001 Nano n 10-9 0.000000001 Name Symbol Size factor or   nano n 10-9 micro m 10-6 milli 10-3 centi c 10-2 kilo k 103 Mega M 106

Converting Unit Quantities Science Skills Converting Unit Quantities Examples: 665cm 1m 6.65m 10^2cm 665km 10^3m 6.65x105m 1km

Converting Unit Quantities Science Skills Converting Unit Quantities Examples (cont.): 40ns = 1s/10^9 ns= 4x10-8s

Converting Unit Quantities Science Skills Converting Unit Quantities Examples (cont.): 12km = _____________m 225mm = ____________m 34cm = ______________m 650nm = _____________m

Converting Unit Quantities Science Skills Converting Unit Quantities Examples (cont.): 180g = _____________kg 125mg = ____________kg 43mg = ______________kg

Converting Unit Quantities Science Skills Converting Unit Quantities Examples (cont.): 450ns = _____________s 22min = ____________s 4hrs 12min = ______________s

Science Skills Measurement Precision Accuracy Your Ability to Reproduce Measurements Accuracy How Close is Your Measurement to the Actual Measurement? Precise Accurate

Science Skills Presenting Data Tables Graphs A 3 B 7 C 10 D 2 F 1 Letter Grade # of Students A 3 B 7 C 10 D 2 F 1 Grade Distribution for Spring 2007

Graphs Science Skills Variables Independent Variable (IV) Manipulated by the Experimenter Represented on the “x” axis Dependant Variable (DV) The Measured Variable Represented on the “y” axis