Uncategorised (JEE Advanced Physics by BM Sharma + GMP Solutions)

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In figure, electromagnetic radiations of wavelength 200 nm are incident on a metallic plate A. The photoelectrons are accelerated by a potential difference of 10 V. These electrons
14
Oct
In figure, electromagnetic radiations of wavelength 200 nm are incident on a metallic plate A. The photoelectrons are accelerated by a potential difference of 10 V. These electrons electromagnetic radiations of wavelength 200 nm are incident on a metallic plate A. The photoelectrons are accelerated by a potential difference of 10 V. These electrons In [...]
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Tags: electromagnetic radiations of wavelength 200 nm are incident on a metallic plate A. The photoelectrons are accelerated by a potential difference of 10 V. These electrons , In figure ,
An electron of mass m when accelerated through a potential difference V, has a de Broglie wavelength lemda. The de-Broglie wavelength associated with a particle of mass m/4 and charge
14
Oct
An electron of mass m when accelerated through a potential difference V, has a de Broglie wavelength lemda. The de-Broglie wavelength associated with a particle of mass m/4 and charge An electron of mass m when accelerated through a potential difference V has a de Broglie wavelength lemda. The de-Broglie wavelength associated with a particle [...]
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Tags: An electron of mass m when accelerated through a potential difference V , has a de Broglie wavelength lemda. The de-Broglie wavelength associated with a particle of mass m/4 and charge ,
In the arrangement shown in figure y = 1.0 mm, d= 0.24 mm and D = 1.2 m. The work function of the material of the emitter is 2.2 eV. Find the stopping potential V needed to stop the photocurrent
14
Oct
In the arrangement shown in figure y = 1.0 mm, d= 0.24 mm and D = 1.2 m. The work function of the material of the emitter is 2.2 eV. Find the stopping potential V needed to stop the photocurrent d= 0.24 mm and D = 1.2 m. The work function of the material of [...]
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Tags: d= 0.24 mm and D = 1.2 m. The work function of the material of the emitter is 2.2 eV. Find the stopping potential V needed to stop the photocurrent , In the arrangement shown in figure y = 1.0 mm ,
A silver ball of radius 4.8 cm is suspended by a thread in a vacuum chamber. Ultraviolet light of wavelength 200 nm is incident on the ball for some time during which a total light
14
Oct
A silver ball of radius 4.8 cm is suspended by a thread in a vacuum chamber. Ultraviolet light of wavelength 200 nm is incident on the ball for some time during which a total light A silver ball of radius 4.8 cm is suspended by a thread in a vacuum chamber. Ultraviolet light of wavelength [...]
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Tags: A silver ball of radius 4.8 cm is suspended by a thread in a vacuum chamber. Ultraviolet light of wavelength 200 nm is incident on the ball for some time during which a total light ,
A totally reflecting, small plane mirror placed horizontally faces a parallel beam of light as shown in the figure. The mass of the mirror is 20 g. Assume that there is no absorption in the lens and that
14
Oct
A totally reflecting, small plane mirror placed horizontally faces a parallel beam of light as shown in the figure. The mass of the mirror is 20 g. Assume that there is no absorption in the lens and that A totally reflecting small plane mirror placed horizontally faces a parallel beam of light as shown in [...]
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Tags: A totally reflecting , small plane mirror placed horizontally faces a parallel beam of light as shown in the figure. The mass of the mirror is 20 g. Assume that there is no absorption in the lens and that ,
A parallel beam of monochromatic light of wavelength 663 nm is incident on a totally reflecting plane mirror. The angle of incidence is 60 and the number of photons striking the mirror
14
Oct
A parallel beam of monochromatic light of wavelength 663 nm is incident on a totally reflecting plane mirror. The angle of incidence is 60 and the number of photons striking the mirror A parallel beam of monochromatic light of wavelength 663 nm is incident on a totally reflecting plane mirror. The angle of incidence is [...]
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Tags: A parallel beam of monochromatic light of wavelength 663 nm is incident on a totally reflecting plane mirror. The angle of incidence is 60 and the number of photons striking the mirror ,
A monochromatic source of light operation at 200 W emits 4 * 10^20 photons per second. Find the wavelength of the light ( in * 10^-7 m)
14
Oct
A monochromatic source of light operation at 200 W emits 4 * 10^20 photons per second. Find the wavelength of the light ( in * 10^-7 m) A monochromatic source of light operation at 200 W emits 4 * 10^20 photons per second. Find the wavelength of the light ( in * 10^-7 m) October [...]
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Tags: A monochromatic source of light operation at 200 W emits 4 * 10^20 photons per second. Find the wavelength of the light ( in * 10^-7 m) ,
An element of atomic number 9 emits K alpha X-ray of wavelength lemda. Find the atomic number of the element which emits K alpha X-ray of wavelength 4 lemda.
14
Oct
An element of atomic number 9 emits K alpha X-ray of wavelength lemda. Find the atomic number of the element which emits K alpha X-ray of wavelength 4 lemda. An element of atomic number 9 emits K alpha X-ray of wavelength lemda. Find the atomic number of the element which emits K alpha X-ray of [...]
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Tags: An element of atomic number 9 emits K alpha X-ray of wavelength lemda. Find the atomic number of the element which emits K alpha X-ray of wavelength 4 lemda. ,
The de-Broglie wavelength of an electron moving with a velocity of 1.5 * 10^8 m/s is equal to that of a photon. Find the ratio of the kinetic energy of the photon to that of the electron.
14
Oct
The de-Broglie wavelength of an electron moving with a velocity of 1.5 * 10^8 m/s is equal to that of a photon. Find the ratio of the kinetic energy of the photon to that of the electron. The de-Broglie wavelength of an electron moving with a velocity of 1.5 * 10^8 m/s is equal to [...]
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Tags: The de-Broglie wavelength of an electron moving with a velocity of 1.5 * 10^8 m/s is equal to that of a photon. Find the ratio of the kinetic energy of the photon to that of the electron. ,
The radius of an alpha particle moving in a circle in a constant magnetic field is half of the radius of an electron moving in circular path in the same field. The de Broglie wavelength of
14
Oct
The radius of an alpha particle moving in a circle in a constant magnetic field is half of the radius of an electron moving in circular path in the same field. The de Broglie wavelength of The radius of an alpha particle moving in a circle in a constant magnetic field is half of the [...]
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Tags: The radius of an alpha particle moving in a circle in a constant magnetic field is half of the radius of an electron moving in circular path in the same field. The de Broglie wavelength of ,