New answers tagged energy
-1
votes
Work done by a spring on objects of different masses
Momentum is conserved. So with trolley $A$ and $B$:
$$ p_A + p_B = 0 $$
hence:
$$ p_A = - p_B \equiv p $$
So the kinetic energies are:
$$T_A = \frac{p^2}{2M_A} $$
$$T_B = \frac{p^2}{2M_B} $$
which are ...
1
vote
Work done by a spring on objects of different masses
A simple thought experiment would say NO, but it depends on some clarification. Work done on one of the masses is equal to the integral of spring force over displacement. In the limit of one of the ...
1
vote
Accepted
Energy Conservation Spring Problem
OK I wrote the wrong answer previously, here is a corrected version.
The main observation is that conservation of energy doesn't apply. At least not in the way you are writing it.
Why? Because if ...
-1
votes
How hot can one heat a single atom?
I have to begin by being pedantic. Thermodynamics (the subfield of physics where temperatures, entropy, and pressures are explained) does not make statements about the state of a single atom. Like ...
0
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How hot can one heat a single atom?
I'll start with question #1:
For the radiation to have any effect on the hydrogen atom, it must have a frequency (and therefore a well-defined energy content) that the atom is capable of responding to....
5
votes
How hot can one heat a single atom?
Heat is a thermodynamic concept, applicable to systems with large number of particles (taking Avogadro number $N_A\propto 10^{23}$ as a typical number of particle sin the system). In fact, ...
4
votes
Accepted
What does the equation of the law of conservation of total mechanical energy with deformation energy look like?
The reason you "neglect" deformation energy is that it isn't necessary for the calculation, especially in the case of perfectly elastic contact. The only time you might want to include it ...
2
votes
When do we use $ΔU = mcΔT$?
There is no "$c$", you must always specify under what conditions you measure the heat capacity (OK, sometimes people are lazy and only the context tells you what subscript is operational).
...
3
votes
Accepted
When do we use $ΔU = mcΔT$?
In classical thermodynamics, we usually start with defining the exact differential of the property we want to examine (because we are interested mostly in differences) rather than exact quantities.
...
3
votes
Accepted
Motion of the COM of 2-body system
For your block and wedge system the forces acting on and within it are as shown below with the block treated as a point mass and only the directions shown for the forces $N'''$ and $Mg$.
In terms of ...
3
votes
Motion of the COM of 2-body system
As there were no external forces on the system from when the block was given the velocity 𝑣...
The net external force on the system is $\left[N - \left(M+m\right)g\right]{\hat y}$, where $N$ is the ...
4
votes
Motion of the COM of 2-body system
There is a normal (vertical) force from the ground to the wedge of mass $M$ that allows for a displacement of the COM in the vertical direction. In other words, this is not an isolated two-body system....
0
votes
Accepted
Total Work Done and Energy calculation "error"? - Bike cycling up bridge
I belive the answer should be -410 J provided from the equation:
$$ [W=\Delta KE]$$
The total work is the work by all forces.
0
votes
When a submarine blows its ballast and rises, where did the energy for the ascent come from?
It looks like a lot of people are not understanding @BioPhysicist correct answer. So I will attempt to help...
Buoyant Force is defined as -pgV
(p=fluid density, g=gravitational acceleration, V=...
-1
votes
When a submarine blows its ballast and rises, where did the energy for the ascent come from?
Blowing the ballast takes energy, but that isn't the question.
The energy to rise is from gravity. The submarine is now lighter than the seawater surrounding it ... which is another way of saying the ...
0
votes
Prediction and Work
It has nothing to do with "prediction" If something moves it has kinetic energy, you can change it to any other kind of energy. Thats how one uses moving water or air or a dynamo on a ...
1
vote
Accepted
Prediction and Work
I've had this idea that if you can predict something, you can theoretically extract work from it.
I don't think that is always true. For example, if you have a closed system (i.e. perfectly isolated ...
2
votes
Home position of a wind turbine
If the blades were properly balanced and equal in mass, there should be no preferred resting position. By symmetry, the centre of mass of a three bladed propeller or turbine will be at the axis of ...
6
votes
When a submarine blows its ballast and rises, where did the energy for the ascent come from?
As the submarine sinks, it pushes the water up. If a submarine of volume $V$ goes down a distance $d$ in a fluid of density $\rho$ in a gravitational field of $g$, then it has done $\rho gdV$ of work ...
7
votes
When a submarine blows its ballast and rises, where did the energy for the ascent come from?
It doesn't take a quantity of energy to lift the submarine,
if it achieves neutral buoyancy, because the
rising mass of submarine is balanced by the falling of
ocean water into its previous location.
...
1
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When a submarine blows its ballast and rises, where did the energy for the ascent come from?
This doesn't reconcile with the fact that a neutrally buoyant
submarine can jettison arbitrarily little ballast to surface. You
claim that when going to twice the depth, you need to spend twice the
...
-4
votes
When a submarine blows its ballast and rises, where did the energy for the ascent come from?
The energy came from the thermal energy of the compressed air used to blow the tanks. As the water is blown out, the air molecules collide with the water surface; as the water surface is moving away ...
2
votes
Waves, energy and matter
I'm not a physicist, and I'm not sure how the physicists will vote on this one; but IMO, instead of saying that a wave transports energy, I think it might be closer to the truth to say that a wave is ...
1
vote
When a submarine blows its ballast and rises, where did the energy for the ascent come from?
@BowlOfRed's answer is the correct one. But to further clarify that, let's illustrate the idea with a perpetual motion machine rather than your submarine, as follows.
To begin with, let's construct a ...
0
votes
Waves, energy and matter
What is the physical reason why a wave (mechanical or electromagnetic) can transport only energy and not matter?
An electromagnetic wave, by definition, describes wave behavior related to photons. ...
0
votes
Waves, energy and matter
We like to deal with abstractions that make easier to explain reality. For example, there is no mechanical waves in an idealized rigid body. Any movement at any of its points is instantaneously ...
6
votes
When a submarine blows its ballast and rises, where did the energy for the ascent come from?
The high-pressure air in the compressed air system inside a submarine has a tremendous amount of energy stored in it. That stored energy lets the air perform work against the surrounding high-pressure ...
7
votes
When a submarine blows its ballast and rises, where did the energy for the ascent come from?
Now at depth it blows the tanks and becomes positively buoyant.
This is not free. As the openings are now at depth, it requires a large amount of energy to remove the water. The energy to remove ...
43
votes
Accepted
When a submarine blows its ballast and rises, where did the energy for the ascent come from?
Buoyancy comes from a fluid exerting a net upward force pushing on a submerged object. As a floating object rises, the buoyant force does positive work on the object, and hence negative work is being ...
1
vote
Do gravitational waves cause matter to radiate?
It depends on your exact setup but in theory you could arrange for gravitational waves to generate electromagnetic radiation, however in practice I don't think this scenario is very plausible to occur ...
2
votes
Do gravitational waves cause matter to radiate?
Let us assume that our gravitational waves are described by a linearized Einstein equation, so that the metric is of the form
$$
g_{\mu\nu} = \eta_{\mu\nu} + h_{\mu\nu}
$$
Where $\eta_{\mu\nu}$ is the ...
0
votes
How does gravitational potential energy work in a very large distance?
Initially, they are millions of light-years apart, with the asteroid
slowly moving away from the planet at a velocity exceeding the escape
velocity at that distance (1 cm/century).
Conventionally, ...
0
votes
What is the potential energy and kinetic energy for capacitor and inductor?
In an antenna energy exchange occurs between its electric field and moving current. The dynamics of a half wave dipole are similar to sloshing water in a bathtub. At the instant the water stops ...
2
votes
Accepted
Could thermal or quantum fluctuations in the far future ionize matter?
Yes, this is a consequence of the Herzfeld "paradox", first noted in 1912. The partition function for a sole hydrogen atom is not well behaved, diverging when one takes the infinite number ...
0
votes
What is the potential energy and kinetic energy for capacitor and inductor?
First, let me collect my earlier comments here:
In specifying a Lagrangian, one typically specifies the configuration space and generalized coordinates on it. Terms in the lagrangian are often ...
1
vote
What is the potential energy and kinetic energy for capacitor and inductor?
Kinetic energy is $1/2mv^2$ of a moving mass. The kinetic energy of a current is tiny. First, electrons are $1800$ times lighter than protons and neutrons. And only a fraction of the electrons of ...
4
votes
What is the potential energy and kinetic energy for capacitor and inductor?
In Lagrangian mechanics the criterion is that the solution to the equation corresponds to a point in variation space such that the derivative of the Action with respect to variation is zero.
Let the ...
2
votes
What is the potential energy and kinetic energy for capacitor and inductor?
According to https://en.wikipedia.org/wiki/LC_circuit
the equation for current in an LC-circuit is:
$$ \ddot I(t) + \frac 1 {LC} I(t) = 0 $$
comparing that with a harmonic oscillator:
$$ m\ddot x(t) + ...
0
votes
How is the energy of an electron-shell related to the speed of electrons in that shell?
The counter intuitive phenomenon you describe is the same in both classical and quantum systems. Objects near the earth orbit faster than objects further away. The closer orbits have higher kinetic ...
1
vote
Accepted
Minimum work done on a mass to take it along a path
If the particle begins and ends at rest, there is no change in kinetic energy which means the net work done by all external forces on the particle (gravity, friction and the applied force) is zero, ...
1
vote
The kinetic energy of rigid body
The kinetic energy due to the ball's rotation about its own centre is given by the $\frac 1 2 I \omega^2$ term. So to calculate the kinetic energy due to the ball's revolving around the centre of the ...
3
votes
Energy and force, the basic formula
Notice that
$$ \int d(???)=???$$
your case
$$ E=\int m \,\dot v\, v \ dt =
\int \frac{d}{dt}\left(\frac m2 v^2\right)\,dt=
\int d \left(\frac m2 v^2\right)=\frac m2 v^2\bigg|_0^{v_0}=\frac m2 v_0^2$$
...
1
vote
Acceleration in spring-mass system
You have to assume that the diagram shows the masses undergoing constant acceleration and the spring extension is constant.
Further assumptions are that the strings and massless and inextensible, the ...
6
votes
Energy and force, the basic formula
The chain of equalities that you ask about is haphazard. It's the type of arduous sequence that you get when someone is trying to get to a known end result, without knowing how to get there ...
5
votes
Energy and force, the basic formula
We know that $a=\dot v=\frac{dv}{dt}$ and $v=\dot s=\frac{ds}{dt}$.
Thus we can substitute $a=\dot v$ from the first identity and $ds=vdt$ from the second one.
If you differentiate $\frac{1}{2}mv^2$ ...
2
votes
Accepted
Acceleration in spring-mass system
When the spring is maximally elongated, it will no longer extend and just act like an inextensible string. At this moment, both blocks will act as though they are connected by a massless, inextensible ...
1
vote
Accepted
Elongation of a spring
The OP's comments make clear that this question is not about the equilibrium that will eventually be reached after some oscillation has decayed to zero, but about the oscillation phase.
The OP also ...
1
vote
Where does the activation energy for ATP come from?
I've been researching this question for a while now and here is my crack at it:
So, ATP does actually break down on its own. It takes a few hours for all of it to break down, but we can see it in dead ...
0
votes
Derivation of momentum operator from kinetic energy operator
Your question really is: how can I define the square root of an operator? The answer is diagonalise, replace the eigenvalues by their roots, transform back.
2
votes
Could a crossterm in the energy–momentum relation be missing?
No, it can't be.
The energy-momentum relation
$$E^2=(mc^2)^2+(pc)^2$$
has been confirmed in countless experiments.
An energy-momentum relation with a cross-term $\pm 2mpc^3$ would contradict these ...
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