SIGNIFICANT FIGURES Rules for Significant Figures.

Slides:

Advertisements

Similar presentations

Physics Rules for using Significant Figures. Rules for Averaging Trials Determine the average of the trials using a calculator Determine the uncertainty.

Advertisements

Significant Figures, and Scientific Notation

UNIT ONE TOPIC: Significant Figures and Calculations.

Significant Figures.

NOTES: 3.1, part 2 - Significant Figures

SIGNIFICANT FIGURES Are they significant, or “insignificant”?

MEASUREMENTS. What is the difference between these two measurement rulers? Should we record the same number for each scale reading?

Counting Significant Figures:

Working with Significant Figures. Exact Numbers Some numbers are exact, either because: We count them (there are 14 elephants) By definition (1 inch =

Significant Digits Ch 1 Notes. Significant Digits Used to round measured values when involved in calculations When in scientific notation, all numbers.

Significant Figures & Measurement. How do you know where to round? In math, teachers tell you In math, teachers tell you In science, we use significant.

“Uncertainty in Measurement”

SIG FIGS Section 2-3 Significant Figures Often, precision is limited by the tools available. Significant figures include all known digits plus one estimated.

Significant Numbers All numbers in a measurement that are reasonable and reliable.

Significant Figure Notes With scientific notation too.

1 Significant Figures Significant figures tell us the range of values to expect for repeated measurements The more significant figures there are in a measurement,

Significant Figures What do you write?

Significant Figures and Scientific Notation Significant Figures:Digits that are the result of careful measurement. 1.All non-zero digits are considered.

Significant Figures Rules and Applications. Rules for Determining Significant Figures 1.) All Non-Zero digits are Significant. 1.) All Non-Zero digits.

Significant Figures How to count the number of significant figures in a decimal number. How to count the number of significant figures in a decimal number.

SIGNIFICANT FIGURES AMOLE WHAT & WHY?  Refer to them as “Sig Figs” for short  Used to communicate the degree of precision measured  Example -

MEASUREMENTS. What is the difference between these two measurement rulers? Should we record the same number for each scale reading? The second scale gives.

Significant Figures.

2.3 Using Scientific Measurements. Accuracy vs. Precision  Accuracy- closeness of measurement to correct or accepted value  Precision- closeness of.

Sig figs made easy Or Simply sig fig By Mrs. Painter.

What is the difference between accuracy and precision? Good precision Low accuracy = average position Low precision High accuracy.

Uncertainty in Measurement. Significant Figures #1 All non-zero digits are significant. Examples

Significant Figures. Significant Digits or Significant Figures We must be aware of the accuracy limits of each piece of lab equipment that we use and.

Ch 5 How to take measurements and make proper calculations We will deal with many types of measurements and calculations throughout the year. The types.

Significant Figures. Rule 1: Digits other than zero are significant 96 g = 2 Sig Figs 152 g = __________ Sig Figs 61.4 g = 3 Sig Figs g = __________.

UNIT 2: MEASUREMENT Topics Covered:  Significant Digits.

 1. Nonzero integers. Nonzero integers always count as significant figures. For example, the number 1457 has four nonzero integers, all of which count.

Significant Figures. Rule #1 All non-zero numbers are significant 284 has ____ sig figs 123,456 has _____ sig figs.

SIG FIGURE’S RULE SUMMARY COUNTING #’S and Conversion factors – INFINITE NONZERO DIGIT’S: ALWAYS ZERO’S: LEADING : NEVER CAPTIVE: ALWAYS TRAILING :SOMETIMES.

Rules for Significant Figures

Unit 3 lec 2: Significant Figures

Rules for Significant Figures

Significant Figures Definition: Measurement with Sig Figs:

Significant Figures Sig Figs.

Significant Figures in Calculations

Class Notes: Significant Figures

Significant Figures in Calculations

Aim: Why are Significant Figures Important?

Put lab sheet on corner of your desk for me to pick up “Significant Figures” Do these in composition book: – X

SIG FIGURE’S RULE SUMMARY

Pacific-Atlantic Method

(sig figs if you’re cool)

Significant Figures Notes

Trouble free Significant Figures (Sig.Figs or s.f)

Significant Figures General Chemistry.

Significant Figures Any digit in a measurement that is known with certainty plus one final digit, which is somewhat uncertain or estimated.

DETERMINING SIGNIFICANT FIGURES

Significant Figures All non-zero digits are significant (2.45 has 3 SF) Zeros between (sandwiched)non-zero digits are significant (303 has 3 SF)

Unit 1 lec 3: Significant Figures

Introduction to Significant Figures &

Exact and Inexact Numbers

Section 3-2 Uncertainty in Measurements

Measurement book reference p

Significant Figures, and Scientific Notation

3.1 Continued… Significant Figures

Measurement Accuracy & Precision.

Unit 2: Physics Sc 3200.

How do you determine where to round off your answers?

Significant Figures.

Measurement Day 1 – Sig Figs.

Significant Figures and Rounding

Significant Figures in Calculations

Aim: How do we determine the number of significant figures in a measurement? Warm Up What is the difference between the values of 3, 3.0, and 3.00.

Uncertainty in Measurement

Significant Figures Overview

Presentation transcript:

SIGNIFICANT FIGURES Rules for Significant Figures

A. Read from the left and start counting sig figs when you encounter the first non-zero digit 1. All non zero numbers are significant (meaning they count as sig figs) 613 has three sig figs has six sig figs

2. Zeros located between non-zero digits are significant (they count) 5004 has four sig figs 602 has three sig figs has 16 sig figs!

3. Trailing zeros (those at the end) are significant only if the number contains a decimal point; otherwise they are insignificant (they don’t count) has four sig figs has six sig figs has two sig figs – unless you’re given additional information in the problem

4. Zeros to left of the first nonzero digit are insignificant (they don’t count); they are only placeholders! has three sig figs has two sig figs also has two sig figs!

B. Rules for addition/subtraction problems Your calculated value cannot be more precise than the least precise quantity used in the calculation. The least precise quantity has the fewest digits to the right of the decimal point. Your calculated value will have the same number of digits to the right of the decimal point as that of the least precise quantity.

B. Rules for addition/subtraction problems In practice, find the quantity with the fewest digits to the right of the decimal point. In the example below, this would be 11.1 (this is the least precise quantity) = (this is what your calculator spits out) In this case, your final answer is limited to one sig fig to the right of the decimal or 25.3 (rounded up).

C. Rules for multiplication/division problems The number of sig figs in the final calculated value will be the same as that of the quantity with the fewest number of sig figs used in the calculation. In practice, find the quantity with the fewest number of sig figs. In the example below, the quantity with the fewest number of sig figs is 27.2 (three sig figs). Your final answer is therefore limited to three sig figs.

(27.2 x 15.63) /1.846 = (this is what you calculator spits out) In this case, since your final answer is limited to three sig figs, the answer is 230. (rounded down).

D. Rules for combined addition/subtraction and multiplication/division problems First apply the rules for addition/subtraction (determine the number of sig figs for that step), then apply the rules for multiplication/division ( ) x x 6.8 = sf, 2sf  2sf  39 units

E. Practice Problems 1. Provide the number of sig figs in each of the following numbers: (a) g (b) 3.40 x 103 mL (c) g (d) L (e) g (f) 1020 L

2. Perform the operation and report the answer with the correct number of sig figs. (a) (10.3) x ( ) = (b) (10.3) + ( ) = (c) [(10.3) + ( )] x [(10.3) x ( )] =