MHT-CET Mock Tests Online

Blog Post for testing Math Font

January 29, 2025

Blog Post for testing Math Font

Math Font Name : Cambria Math with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : Cambria Math(non - italic) with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : MJXTEX with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \) \( eV \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)
(7) \( ( \frac{2\pi R^2}{ \pi m e^2} ) \)

Math Font Name : MJXTEX(non-italic) with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)
(7) \( ( \frac{2\pi R^2}{ \pi m e^2} ) \)

Math Font Name : MJXTEX with Georgia

1. In the Bohr model of the hydrogen atom, 55 the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : Noto with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : Katex Main with Noto Sans 1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is: [MHT-CET 2024, May 10, Shift 2] (1) \( 4\alpha \), \( 3\beta \) (2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \) (3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \) (4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \) (5) \( 10.2 \text{eV} \) (6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : Asana Math with Times New Roman

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : DejaVu Math TeX Gyre with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : Latin Modern Math with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : Libertinus Math with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : STIX Math with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : TeX Gyre Schola Math with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : TeX Gyre Pagella Math with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)

Math Font Name : TeX Gyre Schola Math with Noto Sans

1. In the Bohr model of the hydrogen atom, the centripetal force is furnished by the Coulomb attraction between the proton and the electron. If ‘\( r_0 \)’ is the radius of the ground state orbit, ‘\( m \)’ is the mass, ‘\( e \)’ is the charge on the electron, and ‘\( \epsilon_0 \)’ is the permittivity of vacuum, the speed of the electron is:

[MHT-CET 2024, May 10, Shift 2]

(1) \( 4\alpha \), \( 3\beta \)
(2) \( \frac{5l}{\sqrt{\epsilon_0 r_0 m }} \)
(3) \( \frac{e}{\sqrt{6 \pi \epsilon_0 r_0 m 9}} \)
(4) \( \frac{\sqrt{7 \pi \epsilon_0 r_0 m}}{m^1 r^8} \)
(5) \( 10.2 \text{eV} \)
(6) \( \frac{4 \epsilon n^2 h^2}{ \pi m e^2} \)