The complete equation for the given radioactive decay and identify the missing particle B 4 9 e + ? → L 3 6 i + H 2 4 e

Question

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Answer 1

Question

Chapter 14, Problem 14.12PAE

(a)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

B49e+ ? → L36i +H24e

(a)

Expert Solution

Explanation of Solution

Because this is an alpha decay, the helium nucleus is ejected with decrease in mass number by 4 and atomic number by 2 of the parent nucleus. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 6+4−9=1. Similarly, atomic number of the missing particle is 3+2−4=1. The nucleus of atomic number 1 is Hydrogen. Hence, the equation is:

B49e+ H11 → L36i +H24e

(b)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

? +n01 → N1124a +H24e

(b)

Expert Solution

Explanation of Solution

In case of alpha decay, the helium nucleus is ejected. By balancing the mass numbers of products with that of a parent nuclei, the mass number of missing particle is 24+4−1=27. Similarly, atomic number of the missing particle is 11+2−0=13. The nucleus of atomic number 13 is Aluminum. Hence, the equation is:

A1327l +n01 → N1124a +H24e

(c)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

C2040a+ ? → K1940 + H11

(c)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 40+1−40=1. Similarly, atomic number of the missing particle is 19+1−20=0. The particle with atomic number 0 and mass number 1 is Neutron. Hence, the equation is:

C2040a+ n01 → K1940 + H11

(d)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

A95241m+ H24e → B97243k + ?

(d)

Expert Solution

Explanation of Solution

By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 241+4−243=2. Similarly, atomic number of the missing particle is 95+2−97=0. The particle with 0 mass number is neutron. Hence, the equation is:

A95241m+ H24e → B97243k + 2n01

(e)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

C96246m +C612 → 4n01 + ?

(e)

Expert Solution

Explanation of Solution

In case of neutron decay, the mass number gets reduced. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 246+12−4×1=254. Similarly, atomic number of the missing particle is 96+6−4×0=102. The nucleus of atomic number 102 is Nobelium. Hence, the equation is:

C96246m +C612 → 4n01 + N102254o

(f)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

U92238+ ? → F100249m + 5n01

(f)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 249+5×1−238=16. Similarly, atomic number of the missing particle is 100+5×0−92=8. The nucleus with atomic number 8 is Oxygen. Hence, the equation is:

U92238+ O816 → F100249m + 5n01

Conclusion

Therefore, if one of the species from the radioactive decay equation is missing, it can be determined by balancing atomic numbers and atomic mass numbers.

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Students have asked these similar questions

Please help me to figure this out. I got 24 is that correct? Please step by step help.

The initial rates method can be used to determine the rate law for a reaction. using the data for the reaction below, what is the rate law for reaction? A+B-C - ALA] At (mot Trial [A] (mol) (MD 2 1 0.075 [B]( 0.075 mo LS 01350 2 0.075 0.090 0.1944 3 0.090 0.075 0.1350 Report value of k with two significant Figure

Compare trials 1 and 2 where [B] is constant. The rate law can be written as: rate = k[A][B]". rate2 0.090 = 9. rate1 0.010 [A]m 6.0m = 3m [A] m 2.0m

Answer 2

Question

Chapter 14, Problem 14.12PAE

(a)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

B49e+ ? → L36i +H24e

(a)

Expert Solution

Explanation of Solution

Because this is an alpha decay, the helium nucleus is ejected with decrease in mass number by 4 and atomic number by 2 of the parent nucleus. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 6+4−9=1. Similarly, atomic number of the missing particle is 3+2−4=1. The nucleus of atomic number 1 is Hydrogen. Hence, the equation is:

B49e+ H11 → L36i +H24e

(b)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

? +n01 → N1124a +H24e

(b)

Expert Solution

Explanation of Solution

In case of alpha decay, the helium nucleus is ejected. By balancing the mass numbers of products with that of a parent nuclei, the mass number of missing particle is 24+4−1=27. Similarly, atomic number of the missing particle is 11+2−0=13. The nucleus of atomic number 13 is Aluminum. Hence, the equation is:

A1327l +n01 → N1124a +H24e

(c)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

C2040a+ ? → K1940 + H11

(c)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 40+1−40=1. Similarly, atomic number of the missing particle is 19+1−20=0. The particle with atomic number 0 and mass number 1 is Neutron. Hence, the equation is:

C2040a+ n01 → K1940 + H11

(d)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

A95241m+ H24e → B97243k + ?

(d)

Expert Solution

Explanation of Solution

By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 241+4−243=2. Similarly, atomic number of the missing particle is 95+2−97=0. The particle with 0 mass number is neutron. Hence, the equation is:

A95241m+ H24e → B97243k + 2n01

(e)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

C96246m +C612 → 4n01 + ?

(e)

Expert Solution

Explanation of Solution

In case of neutron decay, the mass number gets reduced. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 246+12−4×1=254. Similarly, atomic number of the missing particle is 96+6−4×0=102. The nucleus of atomic number 102 is Nobelium. Hence, the equation is:

C96246m +C612 → 4n01 + N102254o

(f)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

U92238+ ? → F100249m + 5n01

(f)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 249+5×1−238=16. Similarly, atomic number of the missing particle is 100+5×0−92=8. The nucleus with atomic number 8 is Oxygen. Hence, the equation is:

U92238+ O816 → F100249m + 5n01

Conclusion

Therefore, if one of the species from the radioactive decay equation is missing, it can be determined by balancing atomic numbers and atomic mass numbers.

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Answer 3

Question

Chapter 14, Problem 14.12PAE

(a)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

B49e+ ? → L36i +H24e

(a)

Expert Solution

Explanation of Solution

Because this is an alpha decay, the helium nucleus is ejected with decrease in mass number by 4 and atomic number by 2 of the parent nucleus. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 6+4−9=1. Similarly, atomic number of the missing particle is 3+2−4=1. The nucleus of atomic number 1 is Hydrogen. Hence, the equation is:

B49e+ H11 → L36i +H24e

(b)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

? +n01 → N1124a +H24e

(b)

Expert Solution

Explanation of Solution

In case of alpha decay, the helium nucleus is ejected. By balancing the mass numbers of products with that of a parent nuclei, the mass number of missing particle is 24+4−1=27. Similarly, atomic number of the missing particle is 11+2−0=13. The nucleus of atomic number 13 is Aluminum. Hence, the equation is:

A1327l +n01 → N1124a +H24e

(c)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

C2040a+ ? → K1940 + H11

(c)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 40+1−40=1. Similarly, atomic number of the missing particle is 19+1−20=0. The particle with atomic number 0 and mass number 1 is Neutron. Hence, the equation is:

C2040a+ n01 → K1940 + H11

(d)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

A95241m+ H24e → B97243k + ?

(d)

Expert Solution

Explanation of Solution

By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 241+4−243=2. Similarly, atomic number of the missing particle is 95+2−97=0. The particle with 0 mass number is neutron. Hence, the equation is:

A95241m+ H24e → B97243k + 2n01

(e)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

C96246m +C612 → 4n01 + ?

(e)

Expert Solution

Explanation of Solution

In case of neutron decay, the mass number gets reduced. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 246+12−4×1=254. Similarly, atomic number of the missing particle is 96+6−4×0=102. The nucleus of atomic number 102 is Nobelium. Hence, the equation is:

C96246m +C612 → 4n01 + N102254o

(f)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

U92238+ ? → F100249m + 5n01

(f)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 249+5×1−238=16. Similarly, atomic number of the missing particle is 100+5×0−92=8. The nucleus with atomic number 8 is Oxygen. Hence, the equation is:

U92238+ O816 → F100249m + 5n01

Conclusion

Therefore, if one of the species from the radioactive decay equation is missing, it can be determined by balancing atomic numbers and atomic mass numbers.

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Answer 4

Question

Chapter 14, Problem 14.12PAE

(a)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

B49e+ ? → L36i +H24e

(a)

Expert Solution

Explanation of Solution

Because this is an alpha decay, the helium nucleus is ejected with decrease in mass number by 4 and atomic number by 2 of the parent nucleus. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 6+4−9=1. Similarly, atomic number of the missing particle is 3+2−4=1. The nucleus of atomic number 1 is Hydrogen. Hence, the equation is:

B49e+ H11 → L36i +H24e

(b)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

? +n01 → N1124a +H24e

(b)

Expert Solution

Explanation of Solution

In case of alpha decay, the helium nucleus is ejected. By balancing the mass numbers of products with that of a parent nuclei, the mass number of missing particle is 24+4−1=27. Similarly, atomic number of the missing particle is 11+2−0=13. The nucleus of atomic number 13 is Aluminum. Hence, the equation is:

A1327l +n01 → N1124a +H24e

(c)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

C2040a+ ? → K1940 + H11

(c)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 40+1−40=1. Similarly, atomic number of the missing particle is 19+1−20=0. The particle with atomic number 0 and mass number 1 is Neutron. Hence, the equation is:

C2040a+ n01 → K1940 + H11

(d)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

A95241m+ H24e → B97243k + ?

(d)

Expert Solution

Explanation of Solution

By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 241+4−243=2. Similarly, atomic number of the missing particle is 95+2−97=0. The particle with 0 mass number is neutron. Hence, the equation is:

A95241m+ H24e → B97243k + 2n01

(e)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

C96246m +C612 → 4n01 + ?

(e)

Expert Solution

Explanation of Solution

In case of neutron decay, the mass number gets reduced. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 246+12−4×1=254. Similarly, atomic number of the missing particle is 96+6−4×0=102. The nucleus of atomic number 102 is Nobelium. Hence, the equation is:

C96246m +C612 → 4n01 + N102254o

(f)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

U92238+ ? → F100249m + 5n01

(f)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 249+5×1−238=16. Similarly, atomic number of the missing particle is 100+5×0−92=8. The nucleus with atomic number 8 is Oxygen. Hence, the equation is:

U92238+ O816 → F100249m + 5n01

Conclusion

Therefore, if one of the species from the radioactive decay equation is missing, it can be determined by balancing atomic numbers and atomic mass numbers.

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Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Chapter 14, Problem 14.12PAE

(a)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

B49e+ ? → L36i +H24e

(a)

Expert Solution

Explanation of Solution

Because this is an alpha decay, the helium nucleus is ejected with decrease in mass number by 4 and atomic number by 2 of the parent nucleus. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 6+4−9=1. Similarly, atomic number of the missing particle is 3+2−4=1. The nucleus of atomic number 1 is Hydrogen. Hence, the equation is:

B49e+ H11 → L36i +H24e

(b)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

? +n01 → N1124a +H24e

(b)

Expert Solution

Explanation of Solution

In case of alpha decay, the helium nucleus is ejected. By balancing the mass numbers of products with that of a parent nuclei, the mass number of missing particle is 24+4−1=27. Similarly, atomic number of the missing particle is 11+2−0=13. The nucleus of atomic number 13 is Aluminum. Hence, the equation is:

A1327l +n01 → N1124a +H24e

(c)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

C2040a+ ? → K1940 + H11

(c)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 40+1−40=1. Similarly, atomic number of the missing particle is 19+1−20=0. The particle with atomic number 0 and mass number 1 is Neutron. Hence, the equation is:

C2040a+ n01 → K1940 + H11

(d)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

A95241m+ H24e → B97243k + ?

(d)

Expert Solution

Explanation of Solution

By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 241+4−243=2. Similarly, atomic number of the missing particle is 95+2−97=0. The particle with 0 mass number is neutron. Hence, the equation is:

A95241m+ H24e → B97243k + 2n01

(e)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

C96246m +C612 → 4n01 + ?

(e)

Expert Solution

Explanation of Solution

In case of neutron decay, the mass number gets reduced. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 246+12−4×1=254. Similarly, atomic number of the missing particle is 96+6−4×0=102. The nucleus of atomic number 102 is Nobelium. Hence, the equation is:

C96246m +C612 → 4n01 + N102254o

(f)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

U92238+ ? → F100249m + 5n01

(f)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 249+5×1−238=16. Similarly, atomic number of the missing particle is 100+5×0−92=8. The nucleus with atomic number 8 is Oxygen. Hence, the equation is:

U92238+ O816 → F100249m + 5n01

Conclusion

Therefore, if one of the species from the radioactive decay equation is missing, it can be determined by balancing atomic numbers and atomic mass numbers.

Answer 6

Chapter 14, Problem 14.12PAE

(a)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

B49e+ ? → L36i +H24e

(a)

Expert Solution

Explanation of Solution

Because this is an alpha decay, the helium nucleus is ejected with decrease in mass number by 4 and atomic number by 2 of the parent nucleus. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 6+4−9=1. Similarly, atomic number of the missing particle is 3+2−4=1. The nucleus of atomic number 1 is Hydrogen. Hence, the equation is:

B49e+ H11 → L36i +H24e

Answer 7

Chapter 14, Problem 14.12PAE

(a)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

B49e+ ? → L36i +H24e

Answer 8

(a)

Expert Solution

Explanation of Solution

Because this is an alpha decay, the helium nucleus is ejected with decrease in mass number by 4 and atomic number by 2 of the parent nucleus. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 6+4−9=1. Similarly, atomic number of the missing particle is 3+2−4=1. The nucleus of atomic number 1 is Hydrogen. Hence, the equation is:

B49e+ H11 → L36i +H24e

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

(b)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

? +n01 → N1124a +H24e

(b)

Expert Solution

Explanation of Solution

In case of alpha decay, the helium nucleus is ejected. By balancing the mass numbers of products with that of a parent nuclei, the mass number of missing particle is 24+4−1=27. Similarly, atomic number of the missing particle is 11+2−0=13. The nucleus of atomic number 13 is Aluminum. Hence, the equation is:

A1327l +n01 → N1124a +H24e

Answer 13

(b)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

? +n01 → N1124a +H24e

Answer 14

(b)

Expert Solution

Explanation of Solution

In case of alpha decay, the helium nucleus is ejected. By balancing the mass numbers of products with that of a parent nuclei, the mass number of missing particle is 24+4−1=27. Similarly, atomic number of the missing particle is 11+2−0=13. The nucleus of atomic number 13 is Aluminum. Hence, the equation is:

A1327l +n01 → N1124a +H24e

Answer 15

(b)

Expert Solution

Answer 16

(b)

Expert Solution

Answer 17

Expert Solution

Answer 18

(c)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

C2040a+ ? → K1940 + H11

(c)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 40+1−40=1. Similarly, atomic number of the missing particle is 19+1−20=0. The particle with atomic number 0 and mass number 1 is Neutron. Hence, the equation is:

C2040a+ n01 → K1940 + H11

Answer 19

(c)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

C2040a+ ? → K1940 + H11

Answer 20

(c)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 40+1−40=1. Similarly, atomic number of the missing particle is 19+1−20=0. The particle with atomic number 0 and mass number 1 is Neutron. Hence, the equation is:

C2040a+ n01 → K1940 + H11

Answer 21

(c)

Expert Solution

Answer 22

(c)

Expert Solution

Answer 23

Expert Solution

Answer 24

(d)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

A95241m+ H24e → B97243k + ?

(d)

Expert Solution

Explanation of Solution

By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 241+4−243=2. Similarly, atomic number of the missing particle is 95+2−97=0. The particle with 0 mass number is neutron. Hence, the equation is:

A95241m+ H24e → B97243k + 2n01

Answer 25

(d)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

A95241m+ H24e → B97243k + ?

Answer 26

(d)

Expert Solution

Explanation of Solution

By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 241+4−243=2. Similarly, atomic number of the missing particle is 95+2−97=0. The particle with 0 mass number is neutron. Hence, the equation is:

A95241m+ H24e → B97243k + 2n01

Answer 27

(d)

Expert Solution

Answer 28

(d)

Expert Solution

Answer 29

Expert Solution

Answer 30

(e)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

C96246m +C612 → 4n01 + ?

(e)

Expert Solution

Explanation of Solution

In case of neutron decay, the mass number gets reduced. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 246+12−4×1=254. Similarly, atomic number of the missing particle is 96+6−4×0=102. The nucleus of atomic number 102 is Nobelium. Hence, the equation is:

C96246m +C612 → 4n01 + N102254o

Answer 31

(e)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle

C96246m +C612 → 4n01 + ?

Answer 32

(e)

Expert Solution

Explanation of Solution

In case of neutron decay, the mass number gets reduced. By balancing the mass numbers of products with that of parent nuclei, the mass number of missing particle is 246+12−4×1=254. Similarly, atomic number of the missing particle is 96+6−4×0=102. The nucleus of atomic number 102 is Nobelium. Hence, the equation is:

C96246m +C612 → 4n01 + N102254o

Answer 33

(e)

Expert Solution

Answer 34

(e)

Expert Solution

Answer 35

Expert Solution

Answer 36

(f)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

U92238+ ? → F100249m + 5n01

(f)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 249+5×1−238=16. Similarly, atomic number of the missing particle is 100+5×0−92=8. The nucleus with atomic number 8 is Oxygen. Hence, the equation is:

U92238+ O816 → F100249m + 5n01

Conclusion

Therefore, if one of the species from the radioactive decay equation is missing, it can be determined by balancing atomic numbers and atomic mass numbers.

Answer 37

(f)

Interpretation Introduction

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

U92238+ ? → F100249m + 5n01

Answer 38

(f)

Expert Solution

Explanation of Solution

In the given equation, balancing the mass number and atomic number of the product and reactant sides, we get, the mass number of missing particle is 249+5×1−238=16. Similarly, atomic number of the missing particle is 100+5×0−92=8. The nucleus with atomic number 8 is Oxygen. Hence, the equation is:

U92238+ O816 → F100249m + 5n01

Answer 39

(f)

Expert Solution

Answer 40

(f)

Expert Solution

Answer 41

Expert Solution

Answer 42

Conclusion

Therefore, if one of the species from the radioactive decay equation is missing, it can be determined by balancing atomic numbers and atomic mass numbers.

Answer 43

Ch. 14 - Prob. 1CO Ch. 14 - Prob. 2CO Ch. 14 - Prob. 3CO Ch. 14 - Prob. 4CO Ch. 14 - Prob. 5CO Ch. 14 - Prob. 6CO Ch. 14 - Prob. 7CO Ch. 14 - Prob. 8CO Ch. 14 - Prob. 9CO Ch. 14 - Prob. 10CO

The complete equation for the given radioactive decay and identify the missing particle B 4 9 e + ? → L 3 6 i + H 2 4 e

Concept explainers

To determine:

The complete equation for the given radioactive decay and identify the missing particle

B49e+ ? → L36i +H24e

Explanation of Solution

To determine:

The complete equation for the given radioactive decay and identify the missing particle

? +n01 → N1124a +H24e

Explanation of Solution

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

C2040a+ ? → K1940 + H11

Explanation of Solution

To determine:

The complete equation for the given radioactive decay and identify the missing particle

A95241m+ H24e → B97243k + ?

Explanation of Solution

To determine:

The complete equation for the given radioactive decay and identify the missing particle

C96246m +C612 → 4n01 + ?

Explanation of Solution

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

U92238+ ? → F100249m + 5n01

Explanation of Solution

Want to see more full solutions like this?

Chapter 14 Solutions

The complete equation for the given radioactive decay and identify the missing particle B 4 9 e + ? → L 3 6 i + H 2 4 e

Concept explainers

To determine: The complete equation for the given radioactive decay and identify the missing particle B49e+ ? → L36i +H24e

Explanation of Solution

To determine: The complete equation for the given radioactive decay and identify the missing particle ? +n01 → N1124a +H24e

Explanation of Solution

To determine: The complete equation for the given radioactive decay and identify the missing particle: C2040a+ ? → K1940 + H11

Explanation of Solution

To determine: The complete equation for the given radioactive decay and identify the missing particle A95241m+ H24e → B97243k + ?

Explanation of Solution

To determine: The complete equation for the given radioactive decay and identify the missing particle C96246m +C612 → 4n01 + ?

Explanation of Solution

To determine: The complete equation for the given radioactive decay and identify the missing particle: U92238+ ? → F100249m + 5n01

Explanation of Solution

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Chapter 14 Solutions

To determine:

The complete equation for the given radioactive decay and identify the missing particle

B49e+ ? → L36i +H24e

To determine:

The complete equation for the given radioactive decay and identify the missing particle

? +n01 → N1124a +H24e

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

C2040a+ ? → K1940 + H11

To determine:

The complete equation for the given radioactive decay and identify the missing particle

A95241m+ H24e → B97243k + ?

To determine:

The complete equation for the given radioactive decay and identify the missing particle

C96246m +C612 → 4n01 + ?

To determine:

The complete equation for the given radioactive decay and identify the missing particle:

U92238+ ? → F100249m + 5n01