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PERIODOS TERRESTRES Y PLANETARIOS: GRAVITY OF MARS LETTER G FREEMASONRY 3.72076 m/s^2 GRAVITY ACCELERATION NEWTON
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De: BARILOCHENSE6999  (Mensaje original) Enviado: 25/12/2024 15:23

Gravity of Mars

 
 
 
Earth vs Mars vs Moon gravity at elevation

The gravity of Mars is a natural phenomenon, due to the law of gravity, or gravitation, by which all things with mass around the planet Mars are brought towards it. It is weaker than Earth's gravity due to the planet's smaller mass. The average gravitational acceleration on Mars is 3.72076 m/s2 (about 38% of the gravity of Earth) and it varies.[1]

In general, topography-controlled isostasy drives the short wavelength free-air gravity anomalies.[2] At the same time, convective flow and finite strength of the mantle lead to long-wavelength planetary-scale free-air gravity anomalies over the entire planet.[3][4] Variation in crustal thickness, magmatic and volcanic activities, impact-induced Moho-uplift, seasonal variation of polar ice caps, atmospheric mass variation and variation of porosity of the crust could also correlate to the lateral variations.[5][6][7][8][9]

Over the years models consisting of an increasing but limited number of spherical harmonics have been produced. Maps produced have included free-air gravity anomalyBouguer gravity anomaly, and crustal thickness. In some areas of Mars there is a correlation between gravity anomalies and topography. Given the known topography, higher resolution gravity field can be inferred. Tidal deformation of Mars by the Sun or Phobos can be measured by its gravity. This reveals how stiff the interior is, and shows that the core is partially liquid. The study of surface gravity of Mars can therefore yield information about different features and provide beneficial information for future Mars landings.

Measurement

[edit]
Rotating spherical harmonic, with ℓ=0 to 4{displaystyle ell =0{	ext{ to }}4} for the vertical, and �=0 to 4{displaystyle m=0{	ext{ to }}4} for the horizontal. For the Martian C20 and C30, they vary with time because of the seasonal variation of mass of the polar ice caps through the annual sublimation-condensation cycle of carbon dioxide.

To understand the gravity of Mars, its gravitational field strength g and gravitational potential U are often measured. Simply, if Mars is assumed to be a static perfectly spherical body of radius RM, provided that there is only one satellite revolving around Mars in a circular orbit and such gravitation interaction is the only force acting in the system, the equation would be

����2=���2,{displaystyle {frac {GMm}{r^{2}}}=mromega ^{2},}

where G is the universal constant of gravitation (commonly taken as G = 6.674 × 10−11 m3 kg−1 s−2),[10] M is the mass of Mars (most updated value: 6.41693 × 1023 kg),[11] m is the mass of the satellite, r is the distance between Mars and the satellite, and {displaystyle omega } is the angular velocity of the satellite, which is also equivalent to 2��{displaystyle {frac {2pi }{T}}} (T is the orbiting period of the satellite).

Therefore, �=����2=�3�2��2=4�3�2�2��2{displaystyle g={frac {GM}{R_{M}^{2}}}={frac {r^{3}omega ^{2}}{R_{M}^{2}}}={frac {4r^{3}pi ^{2}}{T^{2}R_{M}^{2}}}}, where RM is the radius of Mars. With proper measurement, rT, and RM are obtainable parameters from Earth.

However, as Mars is a generic, non-spherical planetary body and influenced by complex geological processes, more accurately, the gravitational potential is described with spherical harmonic functions, following convention in geodesy; see Geopotential model.

�(�,�,�)=−���(1+∑ℓ=2ℓ=�(��)ℓ(�ℓ0�ℓ0(sin⁡�)+∑�=1+ℓ(�ℓ�cos⁡��+�ℓ�sin⁡��)�ℓ�(sin⁡�))),{displaystyle U(r,lambda ,psi )=-{frac {GM}{r}}left(1+sum _{ell =2}^{ell =L}left({frac {R}{r}}
ight)^{ell }left(C_{ell 0}P_{ell }^{0}(sin psi )+sum _{m=1}^{+ell }(C_{ell m}cos mlambda +S_{ell m}sin mlambda )P_{ell }^{m}(sin psi )
ight)
ight),}[12]

where �,�,�{displaystyle r,psi ,lambda } are spherical coordinates of the test point.[12] {displaystyle lambda } is longitude and {displaystyle psi } is latitude. �ℓ�{displaystyle C_{ell m}} and �ℓ�{displaystyle S_{ell m}} are dimensionless harmonic coefficients of degree {displaystyle l} and order {displaystyle m}.[12] �ℓ�{displaystyle P_{ell }^{m}} is the Legendre polynomial of degree {displaystyle l} with �=0{displaystyle m=0} and is the associated Legendre polynomial with �>0{displaystyle m>0}. These are used to describe solutions of Laplace's equation.[12] {displaystyle R} is the mean radius of the planet.[12] The coefficient �ℓ0{displaystyle C_{ell 0}} is sometimes written as ��{displaystyle J_{n}}.

  1. The lower the degree {displaystyle ell } and order {displaystyle m}, the longer wavelength of anomaly it represents. In turn, long-wavelength gravity anomaly is influenced by global geophysical structures.
  2. The higher the degree {displaystyle ell } and order {displaystyle m}, the shorter wavelength of anomaly it represents. For degree over 50, it has been shown that those variations have high correlation with the topography.[13] Geophysical interpretation of surface features could further help deriving a more complete picture of the Martian gravity field, though misleading results could be produced.[13]

The oldest technique in determining the gravity of Mars is through Earth-based observation. Later with the arrival of uncrewed spacecraft, subsequent gravity models were developed from radio tracking data.



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De: BARILOCHENSE6999 Enviado: 25/12/2024 15:41

Gravity On Mars: Help Or Hindrance In Colonization?

23rd Nov 2023
Gravity on Mars: help or hindrance in colonization?

Gravity is a fundamental characteristic of planets and other celestial bodies that has a significant impact on life and physical phenomena. In the next decade, humanity is going to colonize the Moon, and after that, the Red Planet. In this article, we will explore gravity on Mars and its impact on humans. But first, let’s define the concept itself.

What Is Gravity?

Gravity (from the Latin gravis, “heavy”) is the universal fundamental interaction between material bodies with mass. In other words, any matter has a gravitational attraction that is proportional to its mass and distance to it. The greater the mass of an object and the closer it is, the greater its gravitational force.

Since the Earth is the most massive object near us (1.317e+25 pounds), all bodies and objects are attracted to it. For example, apples fall to the ground instead of getting attracted to a person’s head. The apple that fell on Newton’s head still fell to the ground later. The gravitational force with which the Earth attracts other bodies to itself is called gravity. The force of gravity is measured by the formula: F = m ⋅ g, where ‘m’ is the mass of the body, and ‘g’ is the gravitational acceleration — a uniformly accelerated motion that all bodies acquire in a vacuum under the influence of gravity near the surface, regardless of their mass.

Free fall acceleration on the Earth’s surface is a constant value that equals 9.8 m/s². This means that when a body is in a free fall, its speed changes by 9.8 m/s in one second. If a body moves vertically upward, its speed decreases by 9.8 m/s in 1 second. If the body moves vertically downward, then the speed increases by 9.8 m/s in 1 second. The gravitational acceleration experienced on the surface of an astronomical or other object is also called surface gravity. So, let’s learn what the surface gravity of Mars is.

How Does Gravity On Mars Compare To Earth, Moon And Venus?

calculating weight on Mars and other planets How to calculate your weight on other planets.

If we take on Earth as 100%, then on Venus, the surface gravity will be 91%, on the Moon — 16.6%, and on Mars — 38%. That is, if you weigh, say, 200 pounds on Earth, then on Venus you would weigh 182 pounds, on Mars — 76 pounds, and on the Moon only — 38! Remember how easily the Apollo astronauts jumped on the Moon even though their spacesuits weighed 130 pounds!

Why Is Mars’ Gravity So Low?

Gravity on different planets and moons depends on their mass and radius square. The greater the mass of the planet and the closer you are to its centre, the stronger the gravity and vice versa. Astronomical objects have different masses and radii, so their g value is also different.

The mass of Mars is approximately 0.107 that of Earth, or approximately 1.523 x 10^23 pounds. The radius of Mars is 2,106 miles, which is almost half that of Earth (3,959 miles). That’s why Mars’s surface gravity is so low.

Would You Fall Faster On Mars?

Since the acceleration of gravity on Mars is almost three times less than on Earth, you might think that you will fall to the Red Planet much more slowly because the gravity of Mars will not pull you as strongly as the Earth’s gravity. But let’s recall that the acceleration of gravity is calculated for bodies in a vacuum and does not take into account the height of the fall and… air resistance. The density of the Martian atmosphere is only 20 grams per cubic meter, which is 61 times less than the density of the Earth’s atmosphere (1.225 kilograms per cubic meter). In other words, the atmospheric resistance on Mars is so low that your final fall speed will be over five times higher than on Earth. Future colonists will need to carefully consider the design of the ship so that it does not crash on the surface at landing.

Is There Enough Gravity On Mars To Walk?

Yes. Even though on Mars, you will weigh almost three times less than on Earth, this disadvantage will be compensated by the spacesuit weight. Neil Armstrong and Buzz Aldrin walked on the Moon with ease, even though there was even less gravity there. In general, you don’t need to be afraid. You’ll have your feet firmly planted on the Red Planet’s surface, and the only thing you’ll need to watch out for is where you step.

Could I Run Faster On Mars?

Running on MarsRunning on Mars. Credit: adme.media

In theory — yes, but there are some other factors to consider. On Earth, marathon speed is 6 miles, and the maximum speed that professional runners can achieve is 27 miles! If we compare gravity on Mars and Earth, then these indicators can be multiplied by 2.7 times. However, on Mars, you won’t be able to run in shorts, a T-shirt, and Nike Air Jordans! There, you will have a heavy spacesuit and boots, protecting you from the harsh conditions of the Martian atmosphere and landscape.

As soon as you step on the surface of the Red Planet, you will see it for yourself! The surface is covered with rust-coloured dust. The dust layer thickness may vary in different places, but on average, it is about two metres! The same fine dust flies in the air, occasionally creating dust storms, the most powerful of which can even be seen from Earth. Let’s agree, this can make running so much more difficult.

Is Mars Gravity Survivable?

Mars colonyMars colony, concept Credit: Getty Images/e71lena

Let’s imagine that we landed safely and even managed to walk on the surface of the Red Planet. Can you survive on Mars in low gravity? Of course, it won’t kill you instantly, but it can have long-term health effects such as bone loss, muscle atrophy, cardiovascular problems, vision problems, and swelling. Astronauts face most of these problems after a long stay on the ISS, and yet, the gravity there is only 12% lower than Earth’s. By the way, read how space medicine fights low-gravity disease.

All in all, to survive on Mars, you will have to try very hard. Astronauts going to Mars will have to exercise regularly and take extra measures to maintain their physical health; technicians and engineers will have to develop special spacesuits that minimize the effect Mars gravity has on humans, as well as create residential complexes with life support systems that replicate terrestrial living conditions to a maximum.

Conclusion

So, we found out that Mars’s gravity is lower than Earth’s, but it allows people to survive and carry out basic vital activities. But there are a couple of nuances. Studying the effects of low gravity on human health and capabilities is an important goal for future missions to Mars and long-term housing on this planet.

Sources:

  • Kenneth L. Nordtvedt, Alan H. Cook, James E. Faller. “Gravity | Definition, Physics, & Facts” https://www.britannica.com/science/gravity-physics
  • NASA science. Mars facts. https://mars.nasa.gov/all-about-mars/facts
  • Here’s How Fast You Could Run on Other Planets https://brightside.me/articles/heres-how-fast-you-could-run-on-other-planets-813714/
  • Chris Denzel. “Gravitational Factors of Our Eight Planets” 2020 https://sciencing.com/gravitational-factors-eight-planets-8439815.html
https://orbitaltoday.com/2023/11/23/gravity-on-mars-help-or-hindrance-in-colonization/

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De: BARILOCHENSE6999 Enviado: 26/12/2024 15:01

Wavelength to Frequency Calculation and Equation


Wavelength to Frequency EquationA simple equation relates wavelength and frequency to the speed of the wave.

The wavelength to frequency and frequency to wavelength calculations are important in physics and engineering. Here is the equation relating wavelength and frequency, example calculations, and a table of common values.

Relationship Between Wavelength and Frequency

A simple equation relates wavelength to frequency:

v = λf

  • v = wave velocity (how fast the wave propagates in a medium)
  • λ = wavelength (distance over which a wave shape repeats)
  • f = wave frequency (number of waves per unit of time)

For light and other electromagnetic radiation in a vacuum, the wave velocity is the speed of light (c):

c = λf

But, the wave speed is different for other kinds of waves and for light passing through a medium.

  • Light in air or vacuum: 299,792,458 meters per second
  • Light in water: 224,901,000 m/s
  • Sound in air: 343.2 m/s
  • Sound in water (20 °C): 1,481 m/s

Wavelength and frequency are inversely proportional. As wavelength increases, frequency decreases. As frequency increases, wavelength decreases.

How to Calculate Wavelength From Frequency

Rearrange the equation and calculate wavelength from frequency:

λ = v/f

For example, find the wavelength of the musical note A4, which has a frequency of 440 Hz.

The only tricky part in the calculation is keeping the units straight. Usually, you work with meters and Hertz and then convert to other units (e.g., nanometers, THz, GHz). In this problem, the wave velocity is the speed of sound in air (343.2 m/s). The frequency is 440 Hz. One hertz unit equal one cycle (wave) per second, so a frequency of 440 Hz is 440 s-1.

λ = v/f
λ = (343.2 m/s)/(440 s-1)
λ = 0.78 m or 78 cm

As another example, find the frequency of the green light of the aurora borealis, which has a frequency of 5.38 x 1014 Hz.

Here, the equation is:

λ = c/f
λ = (3 x 108 m/sec)/(5.38 x 1014 s-1)
λ = 5.576 x 10-7 m = 557.6 nm

How to Calculate Frequency From Wavelength

Rearrange the equation and calculate frequency from wavelength:

f = v/λ

For example, find the wavelength of orange light with a frequency of 4.8×1014 Hz.

f = v/λ (but v is c for light)
f = c/λ
f = (3.00 × 108 m/s)/(4.8×1014 s-1)
f = 6.2 x 10-7 m = 620 nm

Wavelength to Frequency Chart

This chart shows the wavelength to frequency relationship for electromagnetic radiation:

Electromagnetic Radiation Wavelength Frequency
Gamma radiation 1 pm 300 EHz
X-ray 1 nm 300 PHz
Ultraviolet 100 nm 3 PHz
Visible light 400-700 nm 430-750 THz
Infrared 100 μm 3 THz
EHF (Extremely high frequency) 1 mm 300 GHz
SHF (Super high frequency) 1 cm 30 GHz
UHF (Ultra high frequency) 1 dm 3 GHz
VHF (Very high frequency) 10 m 30 MHz
ELF (Extremely low frequency) 100,000 km 3 Hz

References

  • Avison, John (1999). The World of Physics. Nelson Thornes. ISBN 978-0-17-438733-6.
  • Cassidy, David C.; Holton, Gerald James; Rutherford, Floyd James (2002). Understanding Physics. Birkhäuser. ISBN 0-387-98756-8.
  • Hecht, Eugene (1987). Optics (2nd ed.). Addison Wesley. ISBN 0-201-11609-X.
https://sciencenotes.org/wavelength-to-frequency-calculation-and-equation/

Respuesta  Mensaje 4 de 4 en el tema 
De: BARILOCHENSE6999 Enviado: 26/12/2024 15:10

Wavelength to Frequency Calculation and Equation


Wavelength to Frequency EquationA simple equation relates wavelength and frequency to the speed of the wave.

The wavelength to frequency and frequency to wavelength calculations are important in physics and engineering. Here is the equation relating wavelength and frequency, example calculations, and a table of common values.

Relationship Between Wavelength and Frequency

A simple equation relates wavelength to frequency:

v = λf

  • v = wave velocity (how fast the wave propagates in a medium)
  • λ = wavelength (distance over which a wave shape repeats)
  • f = wave frequency (number of waves per unit of time)

For light and other electromagnetic radiation in a vacuum, the wave velocity is the speed of light (c):

c = λf

But, the wave speed is different for other kinds of waves and for light passing through a medium.

  • Light in air or vacuum: 299,792,458 meters per second
  • Light in water: 224,901,000 m/s
  • Sound in air: 343.2 m/s
  • Sound in water (20 °C): 1,481 m/s

Wavelength and frequency are inversely proportional. As wavelength increases, frequency decreases. As frequency increases, wavelength decreases.

How to Calculate Wavelength From Frequency

Rearrange the equation and calculate wavelength from frequency:

λ = v/f

For example, find the wavelength of the musical note A4, which has a frequency of 440 Hz.

The only tricky part in the calculation is keeping the units straight. Usually, you work with meters and Hertz and then convert to other units (e.g., nanometers, THz, GHz). In this problem, the wave velocity is the speed of sound in air (343.2 m/s). The frequency is 440 Hz. One hertz unit equal one cycle (wave) per second, so a frequency of 440 Hz is 440 s-1.

λ = v/f
λ = (343.2 m/s)/(440 s-1)
λ = 0.78 m or 78 cm

As another example, find the frequency of the green light of the aurora borealis, which has a frequency of 5.38 x 1014 Hz.

Here, the equation is:

λ = c/f
λ = (3 x 108 m/sec)/(5.38 x 1014 s-1)
λ = 5.576 x 10-7 m = 557.6 nm

How to Calculate Frequency From Wavelength

Rearrange the equation and calculate frequency from wavelength:

f = v/λ

For example, find the wavelength of orange light with a frequency of 4.8×1014 Hz.

f = v/λ (but v is c for light)
f = c/λ
f = (3.00 × 108 m/s)/(4.8×1014 s-1)
f = 6.2 x 10-7 m = 620 nm

Wavelength to Frequency Chart

This chart shows the wavelength to frequency relationship for electromagnetic radiation:

Electromagnetic Radiation Wavelength Frequency
Gamma radiation 1 pm 300 EHz
X-ray 1 nm 300 PHz
Ultraviolet 100 nm 3 PHz
Visible light 400-700 nm 430-750 THz
Infrared 100 μm 3 THz
EHF (Extremely high frequency) 1 mm 300 GHz
SHF (Super high frequency) 1 cm 30 GHz
UHF (Ultra high frequency) 1 dm 3 GHz
VHF (Very high frequency) 10 m 30 MHz
ELF (Extremely low frequency) 100,000 km 3 Hz

References

  • Avison, John (1999). The World of Physics. Nelson Thornes. ISBN 978-0-17-438733-6.
  • Cassidy, David C.; Holton, Gerald James; Rutherford, Floyd James (2002). Understanding Physics. Birkhäuser. ISBN 0-387-98756-8.
  • Hecht, Eugene (1987). Optics (2nd ed.). Addison Wesley. ISBN 0-201-11609-X.
https://sciencenotes.org/wavelength-to-frequency-calculation-and-equation/


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