3 added
3 removed
Original
2026-01-01
Modified
2026-02-28
1
-
<p>151 Learners</p>
1
+
<p>186 Learners</p>
2
<p>Last updated on<strong>October 29, 2025</strong></p>
2
<p>Last updated on<strong>October 29, 2025</strong></p>
3
<p>Dividing monomials means dividing the numerical coefficients and subtracting the exponents of variables with the same bases. In this article, we will learn about monomials and the steps to divide monomials.</p>
3
<p>Dividing monomials means dividing the numerical coefficients and subtracting the exponents of variables with the same bases. In this article, we will learn about monomials and the steps to divide monomials.</p>
4
<h2>What are Monomials?</h2>
4
<h2>What are Monomials?</h2>
5
<p>What Is Algebra? 🧮 | Simple Explanation with 🎯 Cool Examples for Kids | ✨BrightCHAMPS Math</p>
5
<p>What Is Algebra? 🧮 | Simple Explanation with 🎯 Cool Examples for Kids | ✨BrightCHAMPS Math</p>
6
<p>▶</p>
6
<p>▶</p>
7
<h2>How to divide monomials?</h2>
7
<h2>How to divide monomials?</h2>
8
<p><strong>Dividing monomials:</strong> Separating<a>numbers</a>and variables.<a>Divide</a>the coefficients, then divide like bases by subtracting exponents. Combine results.</p>
8
<p><strong>Dividing monomials:</strong> Separating<a>numbers</a>and variables.<a>Divide</a>the coefficients, then divide like bases by subtracting exponents. Combine results.</p>
9
<p>For example: \(14x^2y7x\) </p>
9
<p>For example: \(14x^2y7x\) </p>
10
<p>Study the coefficients and variables separately. Divide numbers, write every<a>constant</a>and variable in the<a>expression</a>in the<a>expanded form</a>, grouping common bases: 147=2 We divide the<a>common factor</a>from the<a>numerator</a>and the<a>denominator</a>. For example, \(x^2 ÷ x = x^2-1=x\) Combine: 2xy </p>
10
<p>Study the coefficients and variables separately. Divide numbers, write every<a>constant</a>and variable in the<a>expression</a>in the<a>expanded form</a>, grouping common bases: 147=2 We divide the<a>common factor</a>from the<a>numerator</a>and the<a>denominator</a>. For example, \(x^2 ÷ x = x^2-1=x\) Combine: 2xy </p>
11
<h2>How to Divide Monomials with Exponents</h2>
11
<h2>How to Divide Monomials with Exponents</h2>
12
<p>When dividing monomials with exponents, we use the exponent rule. Monomials with the same<a>base</a>are divided by subtracting their exponents. Dividing monomials is different from multiplication. In multiplication, we add the exponents of like<a>bases</a>, but in<a>division</a>, we subtract them. </p>
12
<p>When dividing monomials with exponents, we use the exponent rule. Monomials with the same<a>base</a>are divided by subtracting their exponents. Dividing monomials is different from multiplication. In multiplication, we add the exponents of like<a>bases</a>, but in<a>division</a>, we subtract them. </p>
13
<p>For example \( y^4y^2\) Since both terms have the same base y, subtract the exponent.</p>
13
<p>For example \( y^4y^2\) Since both terms have the same base y, subtract the exponent.</p>
14
<p>\(y^4y^2=y^4-2=y^2\) </p>
14
<p>\(y^4y^2=y^4-2=y^2\) </p>
15
<h3>Explore Our Programs</h3>
15
<h3>Explore Our Programs</h3>
16
-
<p>No Courses Available</p>
17
<h2>How to Divide Monomials with Negative Exponents</h2>
16
<h2>How to Divide Monomials with Negative Exponents</h2>
18
<p>Dividing monomials with<a>negative exponents</a>follows the same exponent rule: subtract the exponents of like bases. However, when subtracting, be careful that negative exponents can result in negative or even positive numbers. In some cases, we rewrite the final answer using positive exponents by applying the rule: </p>
17
<p>Dividing monomials with<a>negative exponents</a>follows the same exponent rule: subtract the exponents of like bases. However, when subtracting, be careful that negative exponents can result in negative or even positive numbers. In some cases, we rewrite the final answer using positive exponents by applying the rule: </p>
19
<p>a-n = 1an </p>
18
<p>a-n = 1an </p>
20
<p>For example:</p>
19
<p>For example:</p>
21
<p>\(18x^5 y^26x^2 y^3\)</p>
20
<p>\(18x^5 y^26x^2 y^3\)</p>
22
<p>Divide the coefficients: 186=3</p>
21
<p>Divide the coefficients: 186=3</p>
23
<p>Subtract exponents for like bases.</p>
22
<p>Subtract exponents for like bases.</p>
24
<p>\(x^5-2=x^3\)</p>
23
<p>\(x^5-2=x^3\)</p>
25
<p>\(y^2-3=y-1\) As the exponent is negative</p>
24
<p>\(y^2-3=y-1\) As the exponent is negative</p>
26
<p>Combine and simplify negative exponents:</p>
25
<p>Combine and simplify negative exponents:</p>
27
<p>\(3x^3 y-1=3x^3y\)</p>
26
<p>\(3x^3 y-1=3x^3y\)</p>
28
<p>\(18x^5 y^26x^2 y3=3x^3y\)</p>
27
<p>\(18x^5 y^26x^2 y3=3x^3y\)</p>
29
<h2>How to Divide Monomials with Negative Coefficients</h2>
28
<h2>How to Divide Monomials with Negative Coefficients</h2>
30
<p>While dividing monomials, divide the coefficients and apply the<a>quotient rule of exponents</a>\(\frac{x^m}{x^n} = x^{m - n} \) for the variables. If both monomials have negative coefficients, the answer will have positive coefficients only. </p>
29
<p>While dividing monomials, divide the coefficients and apply the<a>quotient rule of exponents</a>\(\frac{x^m}{x^n} = x^{m - n} \) for the variables. If both monomials have negative coefficients, the answer will have positive coefficients only. </p>
31
<p>For example: </p>
30
<p>For example: </p>
32
<p>\(\frac{-14x^2}{7x} = -14x^{2-1} = -2x \)</p>
31
<p>\(\frac{-14x^2}{7x} = -14x^{2-1} = -2x \)</p>
33
<p>(Negative positive = negative)</p>
32
<p>(Negative positive = negative)</p>
34
<p>For example: </p>
33
<p>For example: </p>
35
<p>\(\frac{-14x}{-7x} = \frac{-14}{-7} \times \frac{x}{x} = 2 \) </p>
34
<p>\(\frac{-14x}{-7x} = \frac{-14}{-7} \times \frac{x}{x} = 2 \) </p>
36
<p>(Negative negative = positive) </p>
35
<p>(Negative negative = positive) </p>
37
<h2>Tips and Tricks to Master Dividing Monomials</h2>
36
<h2>Tips and Tricks to Master Dividing Monomials</h2>
38
<p>Dividing monomials becomes easy when you follow a few simple rules. These tricks help you simplify expressions quickly and accurately.</p>
37
<p>Dividing monomials becomes easy when you follow a few simple rules. These tricks help you simplify expressions quickly and accurately.</p>
39
<ul><li>Subtract the exponents of like bases when dividing monomials.</li>
38
<ul><li>Subtract the exponents of like bases when dividing monomials.</li>
40
<li>Divide the numerical coefficients separately from the variables.</li>
39
<li>Divide the numerical coefficients separately from the variables.</li>
41
<li>Apply the division rule to each variable individually.</li>
40
<li>Apply the division rule to each variable individually.</li>
42
<li>Rewrite negative exponents as positive by moving them to the denominator. </li>
41
<li>Rewrite negative exponents as positive by moving them to the denominator. </li>
43
<li><p>Cancel common<a>factors</a>to simplify the final expression.</p>
42
<li><p>Cancel common<a>factors</a>to simplify the final expression.</p>
44
</li>
43
</li>
45
</ul><h2>Common Mistakes and How to Avoid Them in Dividing Monomials</h2>
44
</ul><h2>Common Mistakes and How to Avoid Them in Dividing Monomials</h2>
46
<p>While dividing monomials, common mistakes students make include incorrectly applying exponent rules, mixing variables, and mistreating signs. In this section, we will discuss some common mistakes and the way to avoid them while dividing monomials. </p>
45
<p>While dividing monomials, common mistakes students make include incorrectly applying exponent rules, mixing variables, and mistreating signs. In this section, we will discuss some common mistakes and the way to avoid them while dividing monomials. </p>
47
<h2>Real-Life Applications of the Dividing Monomials</h2>
46
<h2>Real-Life Applications of the Dividing Monomials</h2>
48
<p>Dividing monomials is used to calculate the force, interest calculations, distance and time, and many more. In this section, we will learn how it is used in these fields. </p>
47
<p>Dividing monomials is used to calculate the force, interest calculations, distance and time, and many more. In this section, we will learn how it is used in these fields. </p>
49
<ul><li><strong>Calculating Force:</strong>Physicists and engineers use monomials in<a>formulas</a>involving force to design structures, machines, and systems that must withstand specific loads and stresses. Monomials are used in formulae involving force. For example, to find the displacement x in a spring force formula F=kx, divide the total force F by the spring constant (k) to find the displacement (x), x = Fk.</li>
48
<ul><li><strong>Calculating Force:</strong>Physicists and engineers use monomials in<a>formulas</a>involving force to design structures, machines, and systems that must withstand specific loads and stresses. Monomials are used in formulae involving force. For example, to find the displacement x in a spring force formula F=kx, divide the total force F by the spring constant (k) to find the displacement (x), x = Fk.</li>
50
<li><strong>Simple Interest Calculation:</strong>Use by bankers and finance professionals to calculate interest easily. For example, in the formula I = Prt, dividing or rearranging terms r=IPt, such as using<a>monomial</a>division to find the unknown efficiently.</li>
49
<li><strong>Simple Interest Calculation:</strong>Use by bankers and finance professionals to calculate interest easily. For example, in the formula I = Prt, dividing or rearranging terms r=IPt, such as using<a>monomial</a>division to find the unknown efficiently.</li>
51
<li><strong>Time-Speed Formulas:</strong>Use by physicists and engineers. This helps in isolating variables for solving<a>rate</a>or time problems. For example, simplify expressions like d=vt or t=d/v in monomial form.</li>
50
<li><strong>Time-Speed Formulas:</strong>Use by physicists and engineers. This helps in isolating variables for solving<a>rate</a>or time problems. For example, simplify expressions like d=vt or t=d/v in monomial form.</li>
52
<li><strong>Dosage-by-Weight Calculations:</strong>Use by pharmacists and healthcare workers to determine precise dosage. For example, if the common dosage is 10 mg per kg, then a patient with 70 kg would receive: dose =10mg/kg × 70kr=700 mg per kg.</li>
51
<li><strong>Dosage-by-Weight Calculations:</strong>Use by pharmacists and healthcare workers to determine precise dosage. For example, if the common dosage is 10 mg per kg, then a patient with 70 kg would receive: dose =10mg/kg × 70kr=700 mg per kg.</li>
53
<li><strong>Profit and Cost Modelling:</strong>Used by economists and business analysts to simplify formula manipulation to optimize production. For example, divide monomial cost or revenue terms to study marginal costs. </li>
52
<li><strong>Profit and Cost Modelling:</strong>Used by economists and business analysts to simplify formula manipulation to optimize production. For example, divide monomial cost or revenue terms to study marginal costs. </li>
54
-
</ul><h3>Problem 1</h3>
53
+
</ul><h2>Download Worksheets</h2>
54
+
<h3>Problem 1</h3>
55
<p> 12x^5/ 3x^2</p>
55
<p> 12x^5/ 3x^2</p>
56
<p>Okay, lets begin</p>
56
<p>Okay, lets begin</p>
57
<p>\(\frac{12x^5}{3x^2} = 4x^3 \)</p>
57
<p>\(\frac{12x^5}{3x^2} = 4x^3 \)</p>
58
<h3>Explanation</h3>
58
<h3>Explanation</h3>
59
<p>When dividing monomials, divide the numerical coefficients and then apply the exponent rule \(\frac{a^m}{a^n} = a^{m - n} \). Here, the base 𝑥 is common, so you subtract the exponents (5 - 2). The result gives \(4x^3\), meaning the expression has been simplified correctly. </p>
59
<p>When dividing monomials, divide the numerical coefficients and then apply the exponent rule \(\frac{a^m}{a^n} = a^{m - n} \). Here, the base 𝑥 is common, so you subtract the exponents (5 - 2). The result gives \(4x^3\), meaning the expression has been simplified correctly. </p>
60
<p>Well explained 👍</p>
60
<p>Well explained 👍</p>
61
<h3>Problem 2</h3>
61
<h3>Problem 2</h3>
62
<p>8a^6b^3/ 4a^2b</p>
62
<p>8a^6b^3/ 4a^2b</p>
63
<p>Okay, lets begin</p>
63
<p>Okay, lets begin</p>
64
<p>\(\frac{8a^6b^3}{4a^2b} = 2a^4b^2 \)</p>
64
<p>\(\frac{8a^6b^3}{4a^2b} = 2a^4b^2 \)</p>
65
<h3>Explanation</h3>
65
<h3>Explanation</h3>
66
<p>Each part of the monomial should be divided separately. First, divide the numbers (8 and 4), then handle each variable. For 𝑎, subtract 2 from 6; for 𝑏, subtract 1 from 3. This step-by-step process helps in avoiding confusion, especially when there are multiple variables.</p>
66
<p>Each part of the monomial should be divided separately. First, divide the numbers (8 and 4), then handle each variable. For 𝑎, subtract 2 from 6; for 𝑏, subtract 1 from 3. This step-by-step process helps in avoiding confusion, especially when there are multiple variables.</p>
67
<p>Well explained 👍</p>
67
<p>Well explained 👍</p>
68
<h3>Problem 3</h3>
68
<h3>Problem 3</h3>
69
<p>15x^4y^2/ 5x^2y</p>
69
<p>15x^4y^2/ 5x^2y</p>
70
<p>Okay, lets begin</p>
70
<p>Okay, lets begin</p>
71
<p>\(\frac{15x^4y^2}{5x^2y} = 3x^2y \)</p>
71
<p>\(\frac{15x^4y^2}{5x^2y} = 3x^2y \)</p>
72
<h3>Explanation</h3>
72
<h3>Explanation</h3>
73
<p>This example shows how each part simplifies neatly. Divide 15 by 5 to get 3. Then, since both numerator and denominator have x and y, apply the rule of exponents. The powers of x and y reduce by subtraction, leaving the simpler form \(3x^2y\).</p>
73
<p>This example shows how each part simplifies neatly. Divide 15 by 5 to get 3. Then, since both numerator and denominator have x and y, apply the rule of exponents. The powers of x and y reduce by subtraction, leaving the simpler form \(3x^2y\).</p>
74
<p>Well explained 👍</p>
74
<p>Well explained 👍</p>
75
<h3>Problem 4</h3>
75
<h3>Problem 4</h3>
76
<p>6m^3n^5/ 2mn^2</p>
76
<p>6m^3n^5/ 2mn^2</p>
77
<p>Okay, lets begin</p>
77
<p>Okay, lets begin</p>
78
<p>\(\frac{2m^n}{6m^3n^5} = \frac{3}{m^2n^3} \)</p>
78
<p>\(\frac{2m^n}{6m^3n^5} = \frac{3}{m^2n^3} \)</p>
79
<h3>Explanation</h3>
79
<h3>Explanation</h3>
80
<p>In this question, divide the coefficients first. Then, for each variable, subtract the exponents of the same base in the denominator from the numerator. The expression simplifies to \(3m^2n^3\), showing how exponent subtraction works even with multiple variables.</p>
80
<p>In this question, divide the coefficients first. Then, for each variable, subtract the exponents of the same base in the denominator from the numerator. The expression simplifies to \(3m^2n^3\), showing how exponent subtraction works even with multiple variables.</p>
81
<p>Well explained 👍</p>
81
<p>Well explained 👍</p>
82
<h3>Problem 5</h3>
82
<h3>Problem 5</h3>
83
<p>9x^2y^3/ 3x^5y</p>
83
<p>9x^2y^3/ 3x^5y</p>
84
<p>Okay, lets begin</p>
84
<p>Okay, lets begin</p>
85
<p>\(\frac{3x^5y^9}{x^2y^3} = 3x^3y^6 \)</p>
85
<p>\(\frac{3x^5y^9}{x^2y^3} = 3x^3y^6 \)</p>
86
<h3>Explanation</h3>
86
<h3>Explanation</h3>
87
<p>When the exponent in the denominator is greater than the one in the numerator, the result becomes negative. A negative exponent means that the base moves to the denominator. Therefore, \(x^-3\) is rewritten as \(\frac{1}{x^3}\), making the final simplified form \(\frac{3y^2}{x^3}\). This helps students understand how to handle negative exponents in division problems.</p>
87
<p>When the exponent in the denominator is greater than the one in the numerator, the result becomes negative. A negative exponent means that the base moves to the denominator. Therefore, \(x^-3\) is rewritten as \(\frac{1}{x^3}\), making the final simplified form \(\frac{3y^2}{x^3}\). This helps students understand how to handle negative exponents in division problems.</p>
88
<p>Well explained 👍</p>
88
<p>Well explained 👍</p>
89
<h2>FAQs of the Dividing Monomials</h2>
89
<h2>FAQs of the Dividing Monomials</h2>
90
<h3>1.What is a monomial?</h3>
90
<h3>1.What is a monomial?</h3>
91
<p>Monomials are the<a>polynomials</a>with single algebraic terms, for example, 5x2, 6xy, 8y2. </p>
91
<p>Monomials are the<a>polynomials</a>with single algebraic terms, for example, 5x2, 6xy, 8y2. </p>
92
<h3>2.What is dividing monomials?</h3>
92
<h3>2.What is dividing monomials?</h3>
93
<p>Dividing monomials involves dividing the coefficients and applying the law of exponents to the variables. </p>
93
<p>Dividing monomials involves dividing the coefficients and applying the law of exponents to the variables. </p>
94
<h3>3.How to divide a monomial with negative exponents?</h3>
94
<h3>3.How to divide a monomial with negative exponents?</h3>
95
<p>To divide monomials with negative exponents, we follow the same rule of dividing monomials and then apply the exponent rules as usual. </p>
95
<p>To divide monomials with negative exponents, we follow the same rule of dividing monomials and then apply the exponent rules as usual. </p>
96
<h3>4. How to divide a monomial with the same base?</h3>
96
<h3>4. How to divide a monomial with the same base?</h3>
97
<p>To divide the monomials with the same base, we subtract exponents of like \base, that is aman =<a>am</a>- n. </p>
97
<p>To divide the monomials with the same base, we subtract exponents of like \base, that is aman =<a>am</a>- n. </p>
98
<h3>5.What is the law of exponents?</h3>
98
<h3>5.What is the law of exponents?</h3>
99
<p>The<a>laws of exponents</a>are rules used to simplify expressions with powers. Here, we subtract the exponents with the same base. It can be represented as aman = am - n </p>
99
<p>The<a>laws of exponents</a>are rules used to simplify expressions with powers. Here, we subtract the exponents with the same base. It can be represented as aman = am - n </p>
100
100