![Problem 3. A magnetic field of 0.12 T is applied on a^{58}Niion of charge +e and mass 9.62 times 10^{-26} kg. 58{1} ion isaccelerated through a potential difference of 3 kV.(a) Find Problem 3. A magnetic field of 0.12 T is applied on a^{58}Niion of charge +e and mass 9.62 times 10^{-26} kg. 58{1} ion isaccelerated through a potential difference of 3 kV.(a) Find](https://wb-qb-sg-oss.bytededu.com/merge/87e4b85c7b5dc6f55517d87e59f00175.jpg)
Problem 3. A magnetic field of 0.12 T is applied on a^{58}Niion of charge +e and mass 9.62 times 10^{-26} kg. 58{1} ion isaccelerated through a potential difference of 3 kV.(a) Find
![A proton (mass = 1.67 * 10^{-27} kg, charge = 1.6 * 10^{-19} C) travelling with speed 1 *10^6 m/s enters a region of space containing a uniform magnetic field of 1.2 A proton (mass = 1.67 * 10^{-27} kg, charge = 1.6 * 10^{-19} C) travelling with speed 1 *10^6 m/s enters a region of space containing a uniform magnetic field of 1.2](https://study.com/cimages/multimages/16/car25866573396606109496.png)
A proton (mass = 1.67 * 10^{-27} kg, charge = 1.6 * 10^{-19} C) travelling with speed 1 *10^6 m/s enters a region of space containing a uniform magnetic field of 1.2
![Tunable homogeneous kG magnetic field production using permanent magnets: Review of Scientific Instruments: Vol 92, No 12 Tunable homogeneous kG magnetic field production using permanent magnets: Review of Scientific Instruments: Vol 92, No 12](https://aip.scitation.org/action/showOpenGraphArticleImage?doi=10.1063/5.0064498&id=images/medium/5.0064498.figures.online.highlight_f1.jpg)
Tunable homogeneous kG magnetic field production using permanent magnets: Review of Scientific Instruments: Vol 92, No 12
![SOLVED:Mass m = 1.80 kg is suspended vertically at rest by an insulating string connected to circuit partially immersed in a magnetic field as in the figure below. The magnetic field has SOLVED:Mass m = 1.80 kg is suspended vertically at rest by an insulating string connected to circuit partially immersed in a magnetic field as in the figure below. The magnetic field has](https://cdn.numerade.com/ask_images/3bf2ab0f2d844ca1877ec65440eb2017.jpg)
SOLVED:Mass m = 1.80 kg is suspended vertically at rest by an insulating string connected to circuit partially immersed in a magnetic field as in the figure below. The magnetic field has
![a) Magnetisation σ [A m 2 kg −1 ] vs. magnetic field B [T], peak value... | Download Scientific Diagram a) Magnetisation σ [A m 2 kg −1 ] vs. magnetic field B [T], peak value... | Download Scientific Diagram](https://www.researchgate.net/publication/307766721/figure/fig3/AS:614018997821464@1523404945580/a-Magnetisation-s-A-m-2-kg-1-vs-magnetic-field-B-T-peak-value-B-03-T-of-a.png)
a) Magnetisation σ [A m 2 kg −1 ] vs. magnetic field B [T], peak value... | Download Scientific Diagram
![A conducting rectangular loop of mass 0.60 kg, resistance 40 ohm, and dimensions a a times b is allowed to fall from rest through a uniform magnetic field which is perpendicular to A conducting rectangular loop of mass 0.60 kg, resistance 40 ohm, and dimensions a a times b is allowed to fall from rest through a uniform magnetic field which is perpendicular to](https://study.com/cimages/multimages/16/eeee2638028759002102455346.png)
A conducting rectangular loop of mass 0.60 kg, resistance 40 ohm, and dimensions a a times b is allowed to fall from rest through a uniform magnetic field which is perpendicular to
![SOLVED:An electron (m = 9.11 X 10-31 kg, q =-1.60 X 10-19 C) in a magnetic field moves at 2780 m/s in a circle of radius 0.0433 m: What is the strength SOLVED:An electron (m = 9.11 X 10-31 kg, q =-1.60 X 10-19 C) in a magnetic field moves at 2780 m/s in a circle of radius 0.0433 m: What is the strength](https://cdn.numerade.com/ask_images/caaf81a3f40240408037c1846be86b90.jpg)
SOLVED:An electron (m = 9.11 X 10-31 kg, q =-1.60 X 10-19 C) in a magnetic field moves at 2780 m/s in a circle of radius 0.0433 m: What is the strength
![Dependence of the squared magnetic field strength (normalized by B0 =... | Download Scientific Diagram Dependence of the squared magnetic field strength (normalized by B0 =... | Download Scientific Diagram](https://www.researchgate.net/profile/A-Solovev-4/publication/226633779/figure/fig3/AS:784571016704000@1564067715227/Dependence-of-the-squared-magnetic-field-strength-normalized-by-B0-025-kG-y-axis-in.png)
Dependence of the squared magnetic field strength (normalized by B0 =... | Download Scientific Diagram
![Magnetism Example Problems with Solutions - The radius of its path is 0 m. a. Which circle in the - StuDocu Magnetism Example Problems with Solutions - The radius of its path is 0 m. a. Which circle in the - StuDocu](https://d20ohkaloyme4g.cloudfront.net/img/document_thumbnails/6c2e2f6ad78c579eff3bc4938ae17753/thumb_1200_1553.png)
Magnetism Example Problems with Solutions - The radius of its path is 0 m. a. Which circle in the - StuDocu
![A proton (mass =1.6times10^(-27)Kg enters into a magnetic field of induction 3T with a velocity of 10^(7)ms^(-1) at 30 to the field.The force on the proton? A proton (mass =1.6times10^(-27)Kg enters into a magnetic field of induction 3T with a velocity of 10^(7)ms^(-1) at 30 to the field.The force on the proton?](https://doubtnut-static.s.llnwi.net/static/web-thumb/643266045_web.png)