Completely agree. But what I often due is enter the information of a politician I really dislike, using their office phone number and email address.

Elon Musk, 1600 Pennsylvania Ave., Washington D.C.?

for him.

🤣🤣🤣🤣🤣 Perfect!!!

In a small way, if a restaurant has only a scan menu, I just walk out.

Verbally order. You can in the lobby but it’ll take 20 minutes.

But, I tend to order things as they are without substitutions. I did try once to substitute something and it was an ordeal. I eventually gave up and went to the counter to wait for a human to appear.

they cannot accomodate me, then I leave.

It's the dumbest 4G LTE phone I could find.

Mostly I use it as a phone.

Sometimes I use it to send and receive texts.

because it saves paper. I like that attention to environmental issues, which is evident in many ways throughout their business. But they have laminated menus if you really want them.

... data harvesting has become so commonplace that we hardly notice it. Except, of course, when an ad featuring the object of a search two minutes ago shows up on every website we visit afterward. Creeps me out.

I remember punch cards that instructed you to not fold, spindle, or mutilate. This is serious next-level shit.

This is just one example. When I looked up tires for my car about 3 years ago I found some Douglas Tires on Walmart's site. They're made by Goodyear and are very good. Still look new and ride great. But, for the next three months I was bombarded by tire ads regardless of what site I went to. I've already bought tires and yet I have to endure relentless tire ads. That really sucks.

If they're going to do this shit, they at least need to provide an opt-out/ad option choice.

I always have Ad blockers on for internet and why I left cable; there are more commercials than content.

But, some sites catch them and to read their content you have to disable them. *sigh* RawStory is one.

Recommend UBlock Origin

That's one of them. I also use Adblock Plus and Adblocker for YouTube.

and 20 min commercials.. Most times if I want to watch a program I record it and then blast thru the commercials when I watch...
m

Since everyone and everthing on the internet and on your "smart" phones and appiances collects data on you I prefer to at least block the ads that they are using the data to direct ads to you as well as the mindless repetitive ads that only cause me to make a mental note never to buy a product or service. Actually got into a discussion with Alexa about her spying where she argued she was not spying; quite amusing.

Been using them for years.

I want choices. It's problematic when they don't give us a choice.

I appreciate many aspects of connectivity and love having DU right on my phone. But most apps and programs etc., are not happening here.

I like knowing I'm not the only one who uses it!

My kids will no longer help me on tech issues.
They tell me to "google it."

Yes, I hate when I look up a recipe and can only get it if I type in my email address.
Then I need to "unsubscribe".

I do have several cookbooks, but they don't contain recipes for things like chia pudding.
My favorite cookbook is my mom's from the 1940's. Meta Givens
There's something nostalgic using a BOOK whose pages are stained and dogeared from decades of loving use.
I bought a second set on ebay, because my original is shedding pages willy-nilly.

When cell phones first came out, my husband insisted that I get one because I had just had a heart attack.
my reply "No way, I do not want a leash!"
Well, I guess almost all of us have those leashes now.

Having to read through someone's life story before getting to the actual recipe is tedious, annoying and just a means to plaster it with advertising.

'CopyMeThat' is a recipe app that strips out all superfluous text, including the need to enter your email address, and presents it in recipe form. You can then decide if it's a recipe you want to save to your collection or just delete it.

It's $25 for the full features and I've gifted it to several friends and relatives. Totally worth the money.

Is the $25 fee recurring, or is it a one shot dealie thing?

They rightly feared what the manufacturing age would do to harm workers.

Specifically automated machines in weaving and fabrication.

Consider that you only have to edit an HTML file for updates and changes. All the barcode does is provide a link to the menu on restaurant's website. It can save on printing costs.

Also, if a restaurant has a website, you can review the menu and pricing ahead of time to see if you really want to give it a shot.

It's all data, printed or 1s and 0s. What matters is whether it's accurate. Learn how to drive.

If you fail to understand the frustrations and concerns being addressed here, you might want to think for just a moment.

is the OP bordering on insulting? I don't even have a coffee machine I use a French press and often grind my own beans manually. So there.

I get that people lament loss of human connectivity and Big Brother invasion, but we have made trade-offs for convenience since consumerism became a thing.

Updated technology, wifi, the internet, is just another interface for human communicative interaction --- like smoke signals and drums --

and, as tools, can be used for good or ill. Our choices start within us. As Bjork says:

All the modern things
Like cars and such
Have always existed
They've just been waiting in a mountain
For the right moment
Listening to the irritating noises
Of dinosaurs and people
Dabbling outside

We are using the flip-flop positive/negative charge states of electricity and its influence and lack thereof upon the charge states of materials, and translating our thoughts in to a binary language of 1s and 0s, that can be multiplexed and packaged to ride upon analog radio waves to each other and reassembled into a form that activates our senses triggering memories of what language and meanings are stored in our brains.

That Americans are baited by bigotry, greed, and convenience headlong into idiocy is lamentable, but subterfuge by the powerful is not new.

So. write me a letter if you care to respond.

So you must not be that worried. I doubt this is the Fort Knox of internet forums. Again, information can be used for good or ill. It is only safe as long as it stays in your head. That's why evil people use torture to try and extract it. Our brains contain knowledge, which can be assembled into information that may or may not have value in a given situation. All creatures need water, food, air, and shelter in order to live. In order to survive to the age of reproduction, we need opportunity and choices. Instinct drives many choices for survival. Intelligence looks outward beyond the immediacy of the lizard brain. The powers that be bait our lizard brains and distract us from altruistic nirvana.

Just be kind to those around you.

Same with watching a movie on your phone.

But a hi res smart phone and some good earbuds work pretty good I think. Especially if your binge watching to catch up on some episodes in your PJs and warm in your blankets.

All the barcode does is provide a link to the menu on restaurant's website.

and trust in the veracity of the accounting and exchanges. Yeah people will try to fuck with that. It's too late to worry whether your info can be exploited. It can be. It is, legally and otherwise. Our representatives in Washington have left us vulnerable to the data robber barons and to government spooks.

And a good grifter doesn't need technology to rip you off.

it's 90% old restaurant menus.

I am also a bit salty about a restaurant I went to lately where they wanted us to scan a QR code (hate), they didn't have their happy hour menu on the QR code, and when we started to order, it turned out my friend and I had each opened a tab for the same thing. The entire experience was annoying. I don't want to go back there now.

Often a menu link will be a pdf download. Yeah the barcode can be annoying. I didn't get them at first. They interact with different phones differently sometimes. They're annoying, convenient, and invasive, all that. But I ain't mad about it.

I especially didn't like when it let us open two tabs for the same thing at the same table.

The previous time we went there, they put all my stuff on my friend's tab and couldn't undo it. She had already given them her card, and there were so many steps to fix it we didn't bother.

Clearly this particular place has problems, but let's just say that I am over QR codes.

But are you talking about the order on line menu while you're sitting at the table? If so there is a place by us that has that. It serves it's purpose there as they are staffed for a busy walk-up with an extensive grill menu and ice cream. They changed locations to a larger new buildout, started serving alcohol and have some nice outdoor seating. The barcode on a small plaque at the tables allows people to grab a seat and order from there. Then one of the kitchen/counter staff will run the food and drinks out to the table. The counter line keeps going for walk up ordering for carry outs.

The on line ordering app in this case allows for separate tabs, which then keeps things neatly accounted per person if that is what one wishes. Some places hand you a tablet or have a small menu kiosk at the table which puts everything on one tab.

we go in, get a drink and order food, then stay for an hour or so and get more drinks. The QR code is more for a fast food experience as you describe it. FTR, I also often have questions about the food (I have a seafood allergy and need to know, for example, if the fries are cooked in the same oil as shrimp, or if there is fish sauce in the curry, or whatever. You can't ask that when ordering through a code).

Like I said, I know how to do it. It's just not how I want to spend my supposed-to-be-relaxing evening.

Last edited Wed Feb 12, 2025, 02:30 PM - Edit history (1)

a good waiter/waitress who gets your pace and attention level. There was a surly waiter at a restaurant we frequented in the 90s. He was one of our favorites in the neighborhood, Andersonville, Chicago. He cracked us up with how some customers didn't get him. They'd get this look on their faces. Not that he was rude or mean. But kind of catty, and he'd kind of give you shit for not being on the ball as a customer. He knew we got him so we would fuck with each other.

An app can't do that.

Condescending much .. ? Please DO tell us - how we should all order our lives - preferences and beliefs. We all have so much to learn from you!
- - - - - - - - - - - - - - - - - - - - - - -

that the OP references?

You started the smack ... And you could always take it down ...

as I notice the condescending comments are still up.

Quantum mechanics is a fundamental theory that describes the behavior of nature at and below the scale of atoms.[2]: 1.1  It is the foundation of all quantum physics, which includes quantum chemistry, quantum field theory, quantum technology, and quantum information science.

Quantum mechanics can describe many systems that classical physics cannot. Classical physics can describe many aspects of nature at an ordinary (macroscopic and (optical) microscopic) scale, but is not sufficient for describing them at very small submicroscopic (atomic and subatomic) scales. Most theories in classical physics can be derived from quantum mechanics as an approximation, valid at large (macroscopic/microscopic) scale.[3]

Quantum systems have bound states that are quantized to discrete values of energy, momentum, angular momentum, and other quantities, in contrast to classical systems where these quantities can be measured continuously. Measurements of quantum systems show characteristics of both particles and waves (wave–particle duality), and there are limits to how accurately the value of a physical quantity can be predicted prior to its measurement, given a complete set of initial conditions (the uncertainty principle).

Quantum mechanics arose gradually from theories to explain observations that could not be reconciled with classical physics, such as Max Planck's solution in 1900 to the black-body radiation problem, and the correspondence between energy and frequency in Albert Einstein's 1905 paper, which explained the photoelectric effect. These early attempts to understand microscopic phenomena, now known as the "old quantum theory", led to the full development of quantum mechanics in the mid-1920s by Niels Bohr, Erwin Schrödinger, Werner Heisenberg, Max Born, Paul Dirac and others. The modern theory is formulated in various specially developed mathematical formalisms. In one of them, a mathematical entity called the wave function provides information, in the form of probability amplitudes, about what measurements of a particle's energy, momentum, and other physical properties may yield.

Overview and fundamental concepts
Quantum mechanics allows the calculation of properties and behaviour of physical systems. It is typically applied to microscopic systems: molecules, atoms and sub-atomic particles. It has been demonstrated to hold for complex molecules with thousands of atoms,[4] but its application to human beings raises philosophical problems, such as Wigner's friend, and its application to the universe as a whole remains speculative.[5] Predictions of quantum mechanics have been verified experimentally to an extremely high degree of accuracy. For example, the refinement of quantum mechanics for the interaction of light and matter, known as quantum electrodynamics (QED), has been shown to agree with experiment to within 1 part in 1012 when predicting the magnetic properties of an electron.[6]

A fundamental feature of the theory is that it usually cannot predict with certainty what will happen, but only give probabilities. Mathematically, a probability is found by taking the square of the absolute value of a complex number, known as a probability amplitude. This is known as the Born rule, named after physicist Max Born. For example, a quantum particle like an electron can be described by a wave function, which associates to each point in space a probability amplitude. Applying the Born rule to these amplitudes gives a probability density function for the position that the electron will be found to have when an experiment is performed to measure it. This is the best the theory can do; it cannot say for certain where the electron will be found. The Schrödinger equation relates the collection of probability amplitudes that pertain to one moment of time to the collection of probability amplitudes that pertain to another.[7]: 67–87 

One consequence of the mathematical rules of quantum mechanics is a tradeoff in predictability between measurable quantities. The most famous form of this uncertainty principle says that no matter how a quantum particle is prepared or how carefully experiments upon it are arranged, it is impossible to have a precise prediction for a measurement of its position and also at the same time for a measurement of its momentum.[7]: 427–435 


An illustration of the double-slit experiment in physics.
Another consequence of the mathematical rules of quantum mechanics is the phenomenon of quantum interference, which is often illustrated with the double-slit experiment. In the basic version of this experiment, a coherent light source, such as a laser beam, illuminates a plate pierced by two parallel slits, and the light passing through the slits is observed on a screen behind the plate.[8]: 102–111 [2]: 1.1–1.8  The wave nature of light causes the light waves passing through the two slits to interfere, producing bright and dark bands on the screen – a result that would not be expected if light consisted of classical particles.[8] However, the light is always found to be absorbed at the screen at discrete points, as individual particles rather than waves; the interference pattern appears via the varying density of these particle hits on the screen. Furthermore, versions of the experiment that include detectors at the slits find that each detected photon passes through one slit (as would a classical particle), and not through both slits (as would a wave).[8]: 109 [9][10] However, such experiments demonstrate that particles do not form the interference pattern if one detects which slit they pass through. This behavior is known as wave–particle duality. In addition to light, electrons, atoms, and molecules are all found to exhibit the same dual behavior when fired towards a double slit.[2]


A (simplified) diagram of Quantum Tunneling, a phenomenon by which a particle may move through a barrier which would be impossible under classical mechanics.
Another non-classical phenomenon predicted by quantum mechanics is quantum tunnelling: a particle that goes up against a potential barrier can cross it, even if its kinetic energy is smaller than the maximum of the potential.[11] In classical mechanics this particle would be trapped. Quantum tunnelling has several important consequences, enabling radioactive decay, nuclear fusion in stars, and applications such as scanning tunnelling microscopy, tunnel diode and tunnel field-effect transistor.[12][13]

When quantum systems interact, the result can be the creation of quantum entanglement: their properties become so intertwined that a description of the whole solely in terms of the individual parts is no longer possible. Erwin Schrödinger called entanglement "...the characteristic trait of quantum mechanics, the one that enforces its entire departure from classical lines of thought".[14] Quantum entanglement enables quantum computing and is part of quantum communication protocols, such as quantum key distribution and superdense coding.[15] Contrary to popular misconception, entanglement does not allow sending signals faster than light, as demonstrated by the no-communication theorem.[15]

Another possibility opened by entanglement is testing for "hidden variables", hypothetical properties more fundamental than the quantities addressed in quantum theory itself, knowledge of which would allow more exact predictions than quantum theory provides. A collection of results, most significantly Bell's theorem, have demonstrated that broad classes of such hidden-variable theories are in fact incompatible with quantum physics. According to Bell's theorem, if nature actually operates in accord with any theory of local hidden variables, then the results of a Bell test will be constrained in a particular, quantifiable way. Many Bell tests have been performed and they have shown results incompatible with the constraints imposed by local hidden variables.[16][17]

It is not possible to present these concepts in more than a superficial way without introducing the mathematics involved; understanding quantum mechanics requires not only manipulating complex numbers, but also linear algebra, differential equations, group theory, and other more advanced subjects.[18][19] Accordingly, this article will present a mathematical formulation of quantum mechanics and survey its application to some useful and oft-studied examples.

Mathematical formulation
Main article: Mathematical formulation of quantum mechanics
In the mathematically rigorous formulation of quantum mechanics, the state of a quantum mechanical system is a vector
ψ
{displaystyle psi } belonging to a (separable) complex Hilbert space
H
{displaystyle {mathcal {H}}}. This vector is postulated to be normalized under the Hilbert space inner product, that is, it obeys
⟨
ψ
,
ψ
⟩
=
1
{displaystyle langle psi ,psi rangle =1}, and it is well-defined up to a complex number of modulus 1 (the global phase), that is,
ψ
{displaystyle psi } and
e
i
α
ψ
{displaystyle e^{ialpha }psi } represent the same physical system. In other words, the possible states are points in the projective space of a Hilbert space, usually called the complex projective space. The exact nature of this Hilbert space is dependent on the system – for example, for describing position and momentum the Hilbert space is the space of complex square-integrable functions
L
2
(
C
)
{displaystyle L^{2 mathbb {C} )}, while the Hilbert space for the spin of a single proton is simply the space of two-dimensional complex vectors
C
2
{displaystyle mathbb {C} ^{2}} with the usual inner product.

Physical quantities of interest – position, momentum, energy, spin – are represented by observables, which are Hermitian (more precisely, self-adjoint) linear operators acting on the Hilbert space. A quantum state can be an eigenvector of an observable, in which case it is called an eigenstate, and the associated eigenvalue corresponds to the value of the observable in that eigenstate. More generally, a quantum state will be a linear combination of the eigenstates, known as a quantum superposition. When an observable is measured, the result will be one of its eigenvalues with probability given by the Born rule: in the simplest case the eigenvalue
λ
{displaystyle lambda } is non-degenerate and the probability is given by
|
⟨
λ
→
,
ψ
⟩
|
2
{displaystyle |langle {vec {lambda }},psi rangle |^{2}}, where
λ
→
{displaystyle {vec {lambda }}} is its associated eigenvector. More generally, the eigenvalue is degenerate and the probability is given by
⟨
ψ
,
P
λ
ψ
⟩
{displaystyle langle psi ,P_{lambda }psi rangle }, where
P
λ
{displaystyle P_{lambda }} is the projector onto its associated eigenspace. In the continuous case, these formulas give instead the probability density.

After the measurement, if result
λ
{displaystyle lambda } was obtained, the quantum state is postulated to collapse to
λ
→
{displaystyle {vec {lambda }}}, in the non-degenerate case, or to
P
λ
ψ
/
⟨
ψ
,
P
λ
ψ
⟩
{textstyle P_{lambda }psi {big /}!{sqrt {langle psi ,P_{lambda }psi rangle }}}, in the general case. The probabilistic nature of quantum mechanics thus stems from the act of measurement. This is one of the most difficult aspects of quantum systems to understand. It was the central topic in the famous Bohr–Einstein debates, in which the two scientists attempted to clarify these fundamental principles by way of thought experiments. In the decades after the formulation of quantum mechanics, the question of what constitutes a "measurement" has been extensively studied. Newer interpretations of quantum mechanics have been formulated that do away with the concept of "wave function collapse" (see, for example, the many-worlds interpretation). The basic idea is that when a quantum system interacts with a measuring apparatus, their respective wave functions become entangled so that the original quantum system ceases to exist as an independent entity (see Measurement in quantum mechanics[20]).

Time evolution of a quantum state
The time evolution of a quantum state is described by the Schrödinger equation:

i
ℏ
∂
∂
t
ψ
(
t
)
=
H
ψ
(
t
)
.
{displaystyle ihbar {frac {partial }{partial t}}psi (t)=Hpsi (t).}
Here
H
{displaystyle H} denotes the Hamiltonian, the observable corresponding to the total energy of the system, and
ℏ
{displaystyle hbar } is the reduced Planck constant. The constant
i
ℏ
{displaystyle ihbar } is introduced so that the Hamiltonian is reduced to the classical Hamiltonian in cases where the quantum system can be approximated by a classical system; the ability to make such an approximation in certain limits is called the correspondence principle.

The solution of this differential equation is given by

ψ
(
t
)
=
e
−
i
H
t
/
ℏ
ψ
(
0
)
.
{displaystyle psi (t)=e^{-iHt/hbar }psi (0).}
The operator
U
(
t
)
=
e
−
i
H
t
/
ℏ
{displaystyle U(t)=e^{-iHt/hbar }} is known as the time-evolution operator, and has the crucial property that it is unitary. This time evolution is deterministic in the sense that – given an initial quantum state
ψ
(
0
)
{displaystyle psi (0)} – it makes a definite prediction of what the quantum state
ψ
(
t
)
{displaystyle psi (t)} will be at any later time.[21]


Fig. 1: Probability densities corresponding to the wave functions of an electron in a hydrogen atom possessing definite energy levels (increasing from the top of the image to the bottom: n = 1, 2, 3, ...) and angular momenta (increasing across from left to right: s, p, d, ...). Denser areas correspond to higher probability density in a position measurement. Such wave functions are directly comparable to Chladni's figures of acoustic modes of vibration in classical physics and are modes of oscillation as well, possessing a sharp energy and thus, a definite frequency. The angular momentum and energy are quantized and take only discrete values like those shown. (As is the case for resonant frequencies in acoustics.)
Some wave functions produce probability distributions that are independent of time, such as eigenstates of the Hamiltonian.[7]: 133–137  Many systems that are treated dynamically in classical mechanics are described by such "static" wave functions. For example, a single electron in an unexcited atom is pictured classically as a particle moving in a circular trajectory around the atomic nucleus, whereas in quantum mechanics, it is described by a static wave function surrounding the nucleus. For example, the electron wave function for an unexcited hydrogen atom is a spherically symmetric function known as an s orbital (Fig. 1).

Analytic solutions of the Schrödinger equation are known for very few relatively simple model Hamiltonians including the quantum harmonic oscillator, the particle in a box, the dihydrogen cation, and the hydrogen atom. Even the helium atom – which contains just two electrons – has defied all attempts at a fully analytic treatment, admitting no solution in closed form.[22][23][24]

However, there are techniques for finding approximate solutions. One method, called perturbation theory, uses the analytic result for a simple quantum mechanical model to create a result for a related but more complicated model by (for example) the addition of a weak potential energy.[7]: 793  Another approximation method applies to systems for which quantum mechanics produces only small deviations from classical behavior. These deviations can then be computed based on the classical motion.[7]: 849 

Uncertainty principle
One consequence of the basic quantum formalism is the uncertainty principle. In its most familiar form, this states that no preparation of a quantum particle can imply simultaneously precise predictions both for a measurement of its position and for a measurement of its momentum.[25][26] Both position and momentum are observables, meaning that they are represented by Hermitian operators. The position operator
X
^
{displaystyle {hat {X}}} and momentum operator
P
^
{displaystyle {hat {P}}} do not commute, but rather satisfy the canonical commutation relation:

[
X
^
,
P
^
]
=
i
ℏ
.
{displaystyle [{hat {X}},{hat {P}}]=ihbar .}
Given a quantum state, the Born rule lets us compute expectation values for both
X
{displaystyle X} and
P
{displaystyle P}, and moreover for powers of them. Defining the uncertainty for an observable by a standard deviation, we have

σ
X
=
⟨
X
2
⟩
−
⟨
X
⟩
2
,
{displaystyle sigma _{X}={textstyle {sqrt {leftlangle X^{2}rightrangle -leftlangle Xrightrangle ^{2}}}},}
and likewise for the momentum:

σ
P
=
⟨
P
2
⟩
−
⟨
P
⟩
2
.
{displaystyle sigma _{P}={sqrt {leftlangle P^{2}rightrangle -leftlangle Prightrangle ^{2}}}.}
The uncertainty principle states that

σ
X
σ
P
≥
ℏ
2
.
{displaystyle sigma _{X}sigma _{P}geq {frac {hbar }{2}}.}
Either standard deviation can in principle be made arbitrarily small, but not both simultaneously.[27] This inequality generalizes to arbitrary pairs of self-adjoint operators
A
{displaystyle A} and
B
{displaystyle B}. The commutator of these two operators is

[
A
,
B
]
=
A
B
−
B
A
,
{displaystyle [A,B]=AB-BA,}
and this provides the lower bound on the product of standard deviations:

σ
A
σ
B
≥
1
2
|
⟨
[
A
,
B
]
⟩
|
.
{displaystyle sigma _{A}sigma _{B}geq {tfrac {1}{2}}left|{bigl langle }[A,B]{bigr rangle }right|.}
Another consequence of the canonical commutation relation is that the position and momentum operators are Fourier transforms of each other, so that a description of an object according to its momentum is the Fourier transform of its description according to its position. The fact that dependence in momentum is the Fourier transform of the dependence in position means that the momentum operator is equivalent (up to an
i
/
ℏ
{displaystyle i/hbar } factor) to taking the derivative according to the position, since in Fourier analysis differentiation corresponds to multiplication in the dual space. This is why in quantum equations in position space, the momentum
p
i
{displaystyle p_{i}} is replaced by
−
i
ℏ
∂
∂
x
{displaystyle -ihbar {frac {partial }{partial x}}}, and in particular in the non-relativistic Schrödinger equation in position space the momentum-squared term is replaced with a Laplacian times
−
ℏ
2
{displaystyle -hbar ^{2}}.[25]

Composite systems and entanglement
When two different quantum systems are considered together, the Hilbert space of the combined system is the tensor product of the Hilbert spaces of the two components. For example, let A and B be two quantum systems, with Hilbert spaces
H
A
{displaystyle {mathcal {H}}_{A}} and
H
B
{displaystyle {mathcal {H}}_{B}}, respectively. The Hilbert space of the composite system is then

H
A
B
=
H
A
⊗
H
B
.
{displaystyle {mathcal {H}}_{AB}={mathcal {H}}_{A}otimes {mathcal {H}}_{B}.}
If the state for the first system is the vector
ψ
A
{displaystyle psi _{A}} and the state for the second system is
ψ
B
{displaystyle psi _{B}}, then the state of the composite system is

ψ
A
⊗
ψ
B
.
{displaystyle psi _{A}otimes psi _{B}.}
Not all states in the joint Hilbert space
H
A
B
{displaystyle {mathcal {H}}_{AB}} can be written in this form, however, because the superposition principle implies that linear combinations of these "separable" or "product states" are also valid. For example, if
ψ
A
{displaystyle psi _{A}} and
ϕ
A
{displaystyle phi _{A}} are both possible states for system
A
{displaystyle A}, and likewise
ψ
B
{displaystyle psi _{B}} and
ϕ
B
{displaystyle phi _{B}} are both possible states for system
B
{displaystyle B}, then

1
2
(
ψ
A
⊗
ψ
B
+
ϕ
A
⊗
ϕ
B
)
{displaystyle {tfrac {1}{sqrt {2}}}left(psi _{A}otimes psi _{B}+phi _{A}otimes phi _{B}right)}
is a valid joint state that is not separable. States that are not separable are called entangled.[28][29]

If the state for a composite system is entangled, it is impossible to describe either component system A or system B by a state vector. One can instead define reduced density matrices that describe the statistics that can be obtained by making measurements on either component system alone. This necessarily causes a loss of information, though: knowing the reduced density matrices of the individual systems is not enough to reconstruct the state of the composite system.[28][29] Just as density matrices specify the state of a subsystem of a larger system, analogously, positive operator-valued measures (POVMs) describe the effect on a subsystem of a measurement performed on a larger system. POVMs are extensively used in quantum information theory.[28][30]

As described above, entanglement is a key feature of models of measurement processes in which an apparatus becomes entangled with the system being measured. Systems interacting with the environment in which they reside generally become entangled with that environment, a phenomenon known as quantum decoherence. This can explain why, in practice, quantum effects are difficult to observe in systems larger than microscopic.[31]

Equivalence between formulations
There are many mathematically equivalent formulations of quantum mechanics. One of the oldest and most common is the "transformation theory" proposed by Paul Dirac, which unifies and generalizes the two earliest formulations of quantum mechanics – matrix mechanics (invented by Werner Heisenberg) and wave mechanics (invented by Erwin Schrödinger).[32] An alternative formulation of quantum mechanics is Feynman's path integral formulation, in which a quantum-mechanical amplitude is considered as a sum over all possible classical and non-classical paths between the initial and final states. This is the quantum-mechanical counterpart of the action principle in classical mechanics.[33]

Symmetries and conservation laws
Main article: Noether's theorem
The Hamiltonian
H
{displaystyle H} is known as the generator of time evolution, since it defines a unitary time-evolution operator
U
(
t
)
=
e
−
i
H
t
/
ℏ
{displaystyle U(t)=e^{-iHt/hbar }} for each value of
t
{displaystyle t}. From this relation between
U
(
t
)
{displaystyle U(t)} and
H
{displaystyle H}, it follows that any observable
A
{displaystyle A} that commutes with
H
{displaystyle H} will be conserved: its expectation value will not change over time.[7]: 471  This statement generalizes, as mathematically, any Hermitian operator
A
{displaystyle A} can generate a family of unitary operators parameterized by a variable
t
{displaystyle t}. Under the evolution generated by
A
{displaystyle A}, any observable
B
{displaystyle B} that commutes with
A
{displaystyle A} will be conserved. Moreover, if
B
{displaystyle B} is conserved by evolution under
A
{displaystyle A}, then
A
{displaystyle A} is conserved under the evolution generated by
B
{displaystyle B}. This implies a quantum version of the result proven by Emmy Noether in classical (Lagrangian) mechanics: for every differentiable symmetry of a Hamiltonian, there exists a corresponding conservation law.

Examples
Free particle
Main article: Free particle

Position space probability density of a Gaussian wave packet moving in one dimension in free space
The simplest example of a quantum system with a position degree of freedom is a free particle in a single spatial dimension. A free particle is one which is not subject to external influences, so that its Hamiltonian consists only of its kinetic energy:

H
=
1
2
m
P
2
=
−
ℏ
2
2
m
d
2
d
x
2
.
{displaystyle H={frac {1}{2m}}P^{2}=-{frac {hbar ^{2}}{2m}}{frac {d^{2}}{dx^{2}}}.}
The general solution of the Schrödinger equation is given by

ψ
(
x
,
t
)
=
1
2
π
∫
−
∞
∞
ψ
^
(
k
,
0
)
e
i
(
k
x
−
ℏ
k
2
2
m
t
)
d
k
,
{displaystyle psi (x,t)={frac {1}{sqrt {2pi }}}int _{-infty }^{infty }{hat {psi } k,0)e^{i(kx-{frac {hbar k^{2}}{2m}}t)}mathrm {d} k,}
which is a superposition of all possible plane waves
e
i
(
k
x
−
ℏ
k
2
2
m
t
)
{displaystyle e^{i(kx-{frac {hbar k^{2}}{2m}}t)}}, which are eigenstates of the momentum operator with momentum
p
=
ℏ
k
{displaystyle p=hbar k}. The coefficients of the superposition are
ψ
^
(
k
,
0
)
{displaystyle {hat {psi } k,0)}, which is the Fourier transform of the initial quantum state
ψ
(
x
,
0
)
{displaystyle psi (x,0)}.

It is not possible for the solution to be a single momentum eigenstate, or a single position eigenstate, as these are not normalizable quantum states.[note 1] Instead, we can consider a Gaussian wave packet:

ψ
(
x
,
0
)
=
1
π
a
4
e
−
x
2
2
a
{displaystyle psi (x,0)={frac {1}{sqrt[{4}]{pi a}}}e^{-{frac {x^{2}}{2a}}}}
which has Fourier transform, and therefore momentum distribution

ψ
^
(
k
,
0
)
=
a
π
4
e
−
a
k
2
2
.
{displaystyle {hat {psi } k,0)={sqrt[{4}]{frac {a}{pi }}}e^{-{frac {ak^{2}}{2}}}.}
We see that as we make
a
{displaystyle a} smaller the spread in position gets smaller, but the spread in momentum gets larger. Conversely, by making
a
{displaystyle a} larger we make the spread in momentum smaller, but the spread in position gets larger. This illustrates the uncertainty principle.

As we let the Gaussian wave packet evolve in time, we see that its center moves through space at a constant velocity (like a classical particle with no forces acting on it). However, the wave packet will also spread out as time progresses, which means that the position becomes more and more uncertain. The uncertainty in momentum, however, stays constant.[34]

Particle in a box

1-dimensional potential energy box (or infinite potential well)
Main article: Particle in a box
The particle in a one-dimensional potential energy box is the most mathematically simple example where restraints lead to the quantization of energy levels. The box is defined as having zero potential energy everywhere inside a certain region, and therefore infinite potential energy everywhere outside that region.[25]: 77–78  For the one-dimensional case in the
x
{displaystyle x} direction, the time-independent Schrödinger equation may be written

−
ℏ
2
2
m
d
2
ψ
d
x
2
=
E
ψ
.
{displaystyle -{frac {hbar ^{2}}{2m}}{frac {d^{2}psi }{dx^{2}}}=Epsi .}
With the differential operator defined by

p
^
x
=
−
i
ℏ
d
d
x
{displaystyle {hat {p}}_{x}=-ihbar {frac {d}{dx}}}the previous equation is evocative of the classic kinetic energy analogue,
1
2
m
p
^
x
2
=
E
,
{displaystyle {frac {1}{2m}}{hat {p}}_{x}^{2}=E,}
with state
ψ
{displaystyle psi } in this case having energy
E
{displaystyle E} coincident with the kinetic energy of the particle.

The general solutions of the Schrödinger equation for the particle in a box are

ψ
(
x
)
=
A
e
i
k
x
+
B
e
−
i
k
x
E
=
ℏ
2
k
2
2
m
{displaystyle psi (x)=Ae^{ikx}+Be^{-ikx}qquad qquad E={frac {hbar ^{2}k^{2}}{2m}}}
or, from Euler's formula,

ψ
(
x
)
=
C
sin
⁡
(
k
x
)
+
D
cos
⁡
(
k
x
)
.
{displaystyle psi (x)=Csin(kx)+Dcos(kx).!}
The infinite potential walls of the box determine the values of
C
,
D
,
{displaystyle C,D,} and
k
{displaystyle k} at
x
=
0
{displaystyle x=0} and
x
=
L
{displaystyle x=L} where
ψ
{displaystyle psi } must be zero. Thus, at
x
=
0
{displaystyle x=0},

ψ
(
0
)
=
0
=
C
sin
⁡
(
0
)
+
D
cos
⁡
(
0
)
=
D
{displaystyle psi (0)=0=Csin(0)+Dcos(0)=D}
and
D
=
0
{displaystyle D=0}. At
x
=
L
{displaystyle x=L},

ψ
(
L
)
=
0
=
C
sin
⁡
(
k
L
)
,
{displaystyle psi (L)=0=Csin(kL),}
in which
C
{displaystyle C} cannot be zero as this would conflict with the postulate that
ψ
{displaystyle psi } has norm 1. Therefore, since
sin
⁡
(
k
L
)
=
0
{displaystyle sin(kL)=0},
k
L
{displaystyle kL} must be an integer multiple of
π
{displaystyle pi },

k
=
n
π
L
n
=
1
,
2
,
3
,
…
.
{displaystyle k={frac {npi }{L}}qquad qquad n=1,2,3,ldots .}
This constraint on
k
{displaystyle k} implies a constraint on the energy levels, yielding

E
n
=
ℏ
2
π
2
n
2
2
m
L
2
=
n
2
h
2
8
m
L
2
.
{displaystyle E_{n}={frac {hbar ^{2}pi ^{2}n^{2}}{2mL^{2}}}={frac {n^{2}h^{2}}{8mL^{2}}}.}
A finite potential well is the generalization of the infinite potential well problem to potential wells having finite depth. The finite potential well problem is mathematically more complicated than the infinite particle-in-a-box problem as the wave function is not pinned to zero at the walls of the well. Instead, the wave function must satisfy more complicated mathematical boundary conditions as it is nonzero in regions outside the well. Another related problem is that of the rectangular potential barrier, which furnishes a model for the quantum tunneling effect that plays an important role in the performance of modern technologies such as flash memory and scanning tunneling microscopy.

Harmonic oscillator
Main article: Quantum harmonic oscillator

Some trajectories of a harmonic oscillator (i.e. a ball attached to a spring) in classical mechanics (A-B) and quantum mechanics (C-H). In quantum mechanics, the position of the ball is represented by a wave (called the wave function), with the real part shown in blue and the imaginary part shown in red. Some of the trajectories (such as C, D, E, and F) are standing waves (or "stationary states&quot . Each standing-wave frequency is proportional to a possible energy level of the oscillator. This "energy quantization" does not occur in classical physics, where the oscillator can have any energy.
As in the classical case, the potential for the quantum harmonic oscillator is given by[7]: 234 

V
(
x
)
=
1
2
m
ω
2
x
2
.
{displaystyle V(x)={frac {1}{2}}momega ^{2}x^{2}.}
This problem can either be treated by directly solving the Schrödinger equation, which is not trivial, or by using the more elegant "ladder method" first proposed by Paul Dirac. The eigenstates are given by

ψ
n
(
x
)
=
1
2
n
n
!
⋅
(
m
ω
π
ℏ
)
1
/
4
⋅
e
−
m
ω
x
2
2
ℏ
⋅
H
n
(
m
ω
ℏ
x
)
,
{displaystyle psi _{n x)={sqrt {frac {1}{2^{n},n!}}}cdot left({frac {momega }{pi hbar }}right)^{1/4}cdot e^{-{frac {momega x^{2}}{2hbar }}}cdot H_{n}left({sqrt {frac {momega }{hbar }}}xright),qquad }
n
=
0
,
1
,
2
,
…
.
{displaystyle n=0,1,2,ldots .}
where Hn are the Hermite polynomials

H
n
(
x
)
=
(
−
1
)
n
e
x
2
d
n
d
x
n
(
e
−
x
2
)
,
{displaystyle H_{n x)=(-1)^{n}e^{x^{2}}{frac {d^{n}}{dx^{n}}}left(e^{-x^{2}}right),}
and the corresponding energy levels are

E
n
=
ℏ
ω
(
n
+
1
2
)
.
{displaystyle E_{n}=hbar omega left(n+{1 over 2}right).}
This is another example illustrating the discretization of energy for bound states.

Mach–Zehnder interferometer

Schematic of a Mach–Zehnder interferometer
The Mach–Zehnder interferometer (MZI) illustrates the concepts of superposition and interference with linear algebra in dimension 2, rather than differential equations. It can be seen as a simplified version of the double-slit experiment, but it is of interest in its own right, for example in the delayed choice quantum eraser, the Elitzur–Vaidman bomb tester, and in studies of quantum entanglement.[35][36]

We can model a photon going through the interferometer by considering that at each point it can be in a superposition of only two paths: the "lower" path which starts from the left, goes straight through both beam splitters, and ends at the top, and the "upper" path which starts from the bottom, goes straight through both beam splitters, and ends at the right. The quantum state of the photon is therefore a vector
ψ
∈
C
2
{displaystyle psi in mathbb {C} ^{2}} that is a superposition of the "lower" path
ψ
l
=
(
1
0
)
{displaystyle psi _{l}={begin{pmatrix}1\0end{pmatrix}}} and the "upper" path
ψ
u
=
(
0
1
)
{displaystyle psi _{u}={begin{pmatrix}0\1end{pmatrix}}}, that is,
ψ
=
α
ψ
l
+
β
ψ
u
{displaystyle psi =alpha psi _{l}+beta psi _{u}} for complex
α
,
β
{displaystyle alpha ,beta }. In order to respect the postulate that
⟨
ψ
,
ψ
⟩
=
1
{displaystyle langle psi ,psi rangle =1} we require that
|
α
|
2
+
|
β
|
2
=
1
{displaystyle |alpha |^{2}+|beta |^{2}=1}.

Both beam splitters are modelled as the unitary matrix
B
=
1
2
(
1
i
i
1
)
{displaystyle B={frac {1}{sqrt {2}}}{begin{pmatrix}1&i\i&1end{pmatrix}}}, which means that when a photon meets the beam splitter it will either stay on the same path with a probability amplitude of
1
/
2
{displaystyle 1/{sqrt {2}}}, or be reflected to the other path with a probability amplitude of
i
/
2
{displaystyle i/{sqrt {2}}}. The phase shifter on the upper arm is modelled as the unitary matrix
P
=
(
1
0
0
e
i
Δ
Φ
)
{displaystyle P={begin{pmatrix}1&0\0&e^{iDelta Phi }end{pmatrix}}}, which means that if the photon is on the "upper" path it will gain a relative phase of
Δ
Φ
{displaystyle Delta Phi }, and it will stay unchanged if it is in the lower path.

A photon that enters the interferometer from the left will then be acted upon with a beam splitter
B
{displaystyle B}, a phase shifter
P
{displaystyle P}, and another beam splitter
B
{displaystyle B}, and so end up in the state

B
P
B
ψ
l
=
i
e
i
Δ
Φ
/
2
(
−
sin
⁡
(
Δ
Φ
/
2
)
cos
⁡
(
Δ
Φ
/
2
)
)
,
{displaystyle BPBpsi _{l}=ie^{iDelta Phi /2}{begin{pmatrix}-sin(Delta Phi /2)\cos(Delta Phi /2)end{pmatrix}},}
and the probabilities that it will be detected at the right or at the top are given respectively by

p
(
u
)
=
|
⟨
ψ
u
,
B
P
B
ψ
l
⟩
|
2
=
cos
2
⁡
Δ
Φ
2
,
{displaystyle p(u)=|langle psi _{u},BPBpsi _{l}rangle |^{2}=cos ^{2}{frac {Delta Phi }{2}},}
p
(
l
)
=
|
⟨
ψ
l
,
B
P
B
ψ
l
⟩
|
2
=
sin
2
⁡
Δ
Φ
2
.
{displaystyle p(l)=|langle psi _{l},BPBpsi _{l}rangle |^{2}=sin ^{2}{frac {Delta Phi }{2}}.}
One can therefore use the Mach–Zehnder interferometer to estimate the phase shift by estimating these probabilities.

It is interesting to consider what would happen if the photon were definitely in either the "lower" or "upper" paths between the beam splitters. This can be accomplished by blocking one of the paths, or equivalently by removing the first beam splitter (and feeding the photon from the left or the bottom, as desired). In both cases, there will be no interference between the paths anymore, and the probabilities are given by
p
(
u
)
=
p
(
l
)
=
1
/
2
{displaystyle p(u)=p(l)=1/2}, independently of the phase
Δ
Φ
{displaystyle Delta Phi }. From this we can conclude that the photon does not take one path or another after the first beam splitter, but rather that it is in a genuine quantum superposition of the two paths.[37]

Applications
Main article: Applications of quantum mechanics
Quantum mechanics has had enormous success in explaining many of the features of our universe, with regard to small-scale and discrete quantities and interactions which cannot be explained by classical methods.[note 2] Quantum mechanics is often the only theory that can reveal the individual behaviors of the subatomic particles that make up all forms of matter (electrons, protons, neutrons, photons, and others). Solid-state physics and materials science are dependent upon quantum mechanics.[38]

In many aspects, modern technology operates at a scale where quantum effects are significant. Important applications of quantum theory include quantum chemistry, quantum optics, quantum computing, superconducting magnets, light-emitting diodes, the optical amplifier and the laser, the transistor and semiconductors such as the microprocessor, medical and research imaging such as magnetic resonance imaging and electron microscopy.[39] Explanations for many biological and physical phenomena are rooted in the nature of the chemical bond, most notably the macro-molecule DNA.

Relation to other scientific theories
Modern physics
H
^
|
ψ
n
(
t
)
⟩
=
i
ℏ
d
d
t
|
ψ
n
(
t
)
⟩
{displaystyle {hat {H}}|psi _{n t)rangle =ihbar {frac {d}{dt}}|psi _{n t)rangle }
G
μ
ν
+
Λ
g
μ
ν
=
κ
T
μ
ν
{displaystyle G_{mu nu }+Lambda g_{mu nu }={kappa }T_{mu nu }}
Schrödinger and Einstein field equations
Founders
Concepts
Branches
Scientists
Categories
vte
Classical mechanics
The rules of quantum mechanics assert that the state space of a system is a Hilbert space and that observables of the system are Hermitian operators acting on vectors in that space – although they do not tell us which Hilbert space or which operators. These can be chosen appropriately in order to obtain a quantitative description of a quantum system, a necessary step in making physical predictions. An important guide for making these choices is the correspondence principle, a heuristic which states that the predictions of quantum mechanics reduce to those of classical mechanics in the regime of large quantum numbers.[40] One can also start from an established classical model of a particular system, and then try to guess the underlying quantum model that would give rise to the classical model in the correspondence limit. This approach is known as quantization.[41]: 299 [42]

When quantum mechanics was originally formulated, it was applied to models whose correspondence limit was non-relativistic classical mechanics. For instance, the well-known model of the quantum harmonic oscillator uses an explicitly non-relativistic expression for the kinetic energy of the oscillator, and is thus a quantum version of the classical harmonic oscillator.[7]: 234 

Complications arise with chaotic systems, which do not have good quantum numbers, and quantum chaos studies the relationship between classical and quantum descriptions in these systems.[41]: 353 

Quantum decoherence is a mechanism through which quantum systems lose coherence, and thus become incapable of displaying many typically quantum effects: quantum superpositions become simply probabilistic mixtures, and quantum entanglement becomes simply classical correlations.[7]: 687–730  Quantum coherence is not typically evident at macroscopic scales, though at temperatures approaching absolute zero quantum behavior may manifest macroscopically.[note 3]

Many macroscopic properties of a classical system are a direct consequence of the quantum behavior of its parts. For example, the stability of bulk matter (consisting of atoms and molecules which would quickly collapse under electric forces alone), the rigidity of solids, and the mechanical, thermal, chemical, optical and magnetic properties of matter are all results of the interaction of electric charges under the rules of quantum mechanics.[43]

Special relativity and electrodynamics
Early attempts to merge quantum mechanics with special relativity involved the replacement of the Schrödinger equation with a covariant equation such as the Klein–Gordon equation or the Dirac equation. While these theories were successful in explaining many experimental results, they had certain unsatisfactory qualities stemming from their neglect of the relativistic creation and annihilation of particles. A fully relativistic quantum theory required the development of quantum field theory, which applies quantization to a field (rather than a fixed set of particles). The first complete quantum field theory, quantum electrodynamics, provides a fully quantum description of the electromagnetic interaction. Quantum electrodynamics is, along with general relativity, one of the most accurate physical theories ever devised.[44][45]

The full apparatus of quantum field theory is often unnecessary for describing electrodynamic systems. A simpler approach, one that has been used since the inception of quantum mechanics, is to treat charged particles as quantum mechanical objects being acted on by a classical electromagnetic field. For example, the elementary quantum model of the hydrogen atom describes the electric field of the hydrogen atom using a classical
−
e
2
/
(
4
π
ϵ
0
r
)
{displaystyle textstyle -e^{2}/(4pi epsilon _{_{0}}r)} Coulomb potential.[7]: 285  Likewise, in a Stern–Gerlach experiment, a charged particle is modeled as a quantum system, while the background magnetic field is described classically.[41]: 26  This "semi-classical" approach fails if quantum fluctuations in the electromagnetic field play an important role, such as in the emission of photons by charged particles.

Quantum field theories for the strong nuclear force and the weak nuclear force have also been developed. The quantum field theory of the strong nuclear force is called quantum chromodynamics, and describes the interactions of subnuclear particles such as quarks and gluons. The weak nuclear force and the electromagnetic force were unified, in their quantized forms, into a single quantum field theory (known as electroweak theory), by the physicists Abdus Salam, Sheldon Glashow and Steven Weinberg.[46]

Relation to general relativity
Even though the predictions of both quantum theory and general relativity have been supported by rigorous and repeated empirical evidence, their abstract formalisms contradict each other and they have proven extremely difficult to incorporate into one consistent, cohesive model. Gravity is negligible in many areas of particle physics, so that unification between general relativity and quantum mechanics is not an urgent issue in those particular applications. However, the lack of a correct theory of quantum gravity is an important issue in physical cosmology and the search by physicists for an elegant "Theory of Everything" (TOE). Consequently, resolving the inconsistencies between both theories has been a major goal of 20th- and 21st-century physics. This TOE would combine not only the models of subatomic physics but also derive the four fundamental forces of nature from a single force or phenomenon.[47]


String vibrations of particles in the quantum world of particles.
One proposal for doing so is string theory, which posits that the point-like particles of particle physics are replaced by one-dimensional objects called strings. String theory describes how these strings propagate through space and interact with each other. On distance scales larger than the string scale, a string looks just like an ordinary particle, with its mass, charge, and other properties determined by the vibrational state of the string. In string theory, one of the many vibrational states of the string corresponds to the graviton, a quantum mechanical particle that carries gravitational force.[48][49]

Another popular theory is loop quantum gravity (LQG), which describes quantum properties of gravity and is thus a theory of quantum spacetime. LQG is an attempt to merge and adapt standard quantum mechanics and standard general relativity. This theory describes space as an extremely fine fabric "woven" of finite loops called spin networks. The evolution of a spin network over time is called a spin foam. The characteristic length scale of a spin foam is the Planck length, approximately 1.616×10−35 m, and so lengths shorter than the Planck length are not physically meaningful in LQG.[50]

Philosophical implications
Main article: Interpretations of quantum mechanics
Unsolved problem in physics:
Is there a preferred interpretation of quantum mechanics? How does the quantum description of reality, which includes elements such as the "superposition of states" and "wave function collapse", give rise to the reality we perceive?
(more unsolved problems in physics)
Since its inception, the many counter-intuitive aspects and results of quantum mechanics have provoked strong philosophical debates and many interpretations. The arguments centre on the probabilistic nature of quantum mechanics, the difficulties with wavefunction collapse and the related measurement problem, and quantum nonlocality. Perhaps the only consensus that exists about these issues is that there is no consensus. Richard Feynman once said, "I think I can safely say that nobody understands quantum mechanics."[51] According to Steven Weinberg, "There is now in my opinion no entirely satisfactory interpretation of quantum mechanics."[52]

The views of Niels Bohr, Werner Heisenberg and other physicists are often grouped together as the "Copenhagen interpretation".[53][54] According to these views, the probabilistic nature of quantum mechanics is not a temporary feature which will eventually be replaced by a deterministic theory, but is instead a final renunciation of the classical idea of "causality". Bohr in particular emphasized that any well-defined application of the quantum mechanical formalism must always make reference to the experimental arrangement, due to the complementary nature of evidence obtained under different experimental situations. Copenhagen-type interpretations were adopted by Nobel laureates in quantum physics, including Bohr,[55] Heisenberg,[56] Schrödinger,[57] Feynman,[2] and Zeilinger[58] as well as 21st-century researchers in quantum foundations.[59]

Albert Einstein, himself one of the founders of quantum theory, was troubled by its apparent failure to respect some cherished metaphysical principles, such as determinism and locality. Einstein's long-running exchanges with Bohr about the meaning and status of quantum mechanics are now known as the Bohr–Einstein debates. Einstein believed that underlying quantum mechanics must be a theory that explicitly forbids action at a distance. He argued that quantum mechanics was incomplete, a theory that was valid but not fundamental, analogous to how thermodynamics is valid, but the fundamental theory behind it is statistical mechanics. In 1935, Einstein and his collaborators Boris Podolsky and Nathan Rosen published an argument that the principle of locality implies the incompleteness of quantum mechanics, a thought experiment later termed the Einstein–Podolsky–Rosen paradox.[note 4] In 1964, John Bell showed that EPR's principle of locality, together with determinism, was actually incompatible with quantum mechanics: they implied constraints on the correlations produced by distance systems, now known as Bell inequalities, that can be violated by entangled particles.[64] Since then several experiments have been performed to obtain these correlations, with the result that they do in fact violate Bell inequalities, and thus falsify the conjunction of locality with determinism.[16][17]

Bohmian mechanics shows that it is possible to reformulate quantum mechanics to make it deterministic, at the price of making it explicitly nonlocal. It attributes not only a wave function to a physical system, but in addition a real position, that evolves deterministically under a nonlocal guiding equation. The evolution of a physical system is given at all times by the Schrödinger equation together with the guiding equation; there is never a collapse of the wave function. This solves the measurement problem.[65]


Schrödinger's cat in the many-worlds interpretation of quantum mechanics, where a branching of the universe occurs through a superposition of two quantum mechanical states.
Everett's many-worlds interpretation, formulated in 1956, holds that all the possibilities described by quantum theory simultaneously occur in a multiverse composed of mostly independent parallel universes.[66] This is a consequence of removing the axiom of the collapse of the wave packet. All possible states of the measured system and the measuring apparatus, together with the observer, are present in a real physical quantum superposition. While the multiverse is deterministic, we perceive non-deterministic behavior governed by probabilities, because we do not observe the multiverse as a whole, but only one parallel universe at a time. Exactly how this is supposed to work has been the subject of much debate. Several attempts have been made to make sense of this and derive the Born rule,[67][68] with no consensus on whether they have been successful.[69][70][71]

Relational quantum mechanics appeared in the late 1990s as a modern derivative of Copenhagen-type ideas,[72] and QBism was developed some years later.[73]

History
Main articles: History of quantum mechanics and Atomic theory
Quantum mechanics was developed in the early decades of the 20th century, driven by the need to explain phenomena that, in some cases, had been observed in earlier times. Scientific inquiry into the wave nature of light began in the 17th and 18th centuries, when scientists such as Robert Hooke, Christiaan Huygens and Leonhard Euler proposed a wave theory of light based on experimental observations.[74] In 1803 English polymath Thomas Young described the famous double-slit experiment.[75] This experiment played a major role in the general acceptance of the wave theory of light.

During the early 19th century, chemical research by John Dalton and Amedeo Avogadro lent weight to the atomic theory of matter, an idea that James Clerk Maxwell, Ludwig Boltzmann and others built upon to establish the kinetic theory of gases. The successes of kinetic theory gave further credence to the idea that matter is composed of atoms, yet the theory also had shortcomings that would only be resolved by the development of quantum mechanics.[76] While the early conception of atoms from Greek philosophy had been that they were indivisible units – the word "atom" deriving from the Greek for "uncuttable" – the 19th century saw the formulation of hypotheses about subatomic structure. One important discovery in that regard was Michael Faraday's 1838 observation of a glow caused by an electrical discharge inside a glass tube containing gas at low pressure. Julius Plücker, Johann Wilhelm Hittorf and Eugen Goldstein carried on and improved upon Faraday's work, leading to the identification of cathode rays, which J. J. Thomson found to consist of subatomic particles that would be called electrons.[77][78]


Max Planck is considered the father of the quantum theory.
The black-body radiation problem was discovered by Gustav Kirchhoff in 1859. In 1900, Max Planck proposed the hypothesis that energy is radiated and absorbed in discrete "quanta" (or energy packets), yielding a calculation that precisely matched the observed patterns of black-body radiation.[79] The word quantum derives from the Latin, meaning "how great" or "how much".[80] According to Planck, quantities of energy could be thought of as divided into "elements" whose size (E) would be proportional to their frequency (ν :

E
=
h
ν

{displaystyle E=hnu },
where h is the Planck constant. Planck cautiously insisted that this was only an aspect of the processes of absorption and emission of radiation and was not the physical reality of the radiation.[81] In fact, he considered his quantum hypothesis a mathematical trick to get the right answer rather than a sizable discovery.[82] However, in 1905 Albert Einstein interpreted Planck's quantum hypothesis realistically and used it to explain the photoelectric effect, in which shining light on certain materials can eject electrons from the material. Niels Bohr then developed Planck's ideas about radiation into a model of the hydrogen atom that successfully predicted the spectral lines of hydrogen.[83] Einstein further developed this idea to show that an electromagnetic wave such as light could also be described as a particle (later called the photon), with a discrete amount of energy that depends on its frequency.[84] In his paper "On the Quantum Theory of Radiation", Einstein expanded on the interaction between energy and matter to explain the absorption and emission of energy by atoms. Although overshadowed at the time by his general theory of relativity, this paper articulated the mechanism underlying the stimulated emission of radiation,[85] which became the basis of the laser.[86]


The 1927 Solvay Conference in Brussels was the fifth world physics conference.
This phase is known as the old quantum theory. Never complete or self-consistent, the old quantum theory was rather a set of heuristic corrections to classical mechanics.[87][88] The theory is now understood as a semi-classical approximation to modern quantum mechanics.[89][90] Notable results from this period include, in addition to the work of Planck, Einstein and Bohr mentioned above, Einstein and Peter Debye's work on the specific heat of solids, Bohr and Hendrika Johanna van Leeuwen's proof that classical physics cannot account for diamagnetism, and Arnold Sommerfeld's extension of the Bohr model to include special-relativistic effects.[87][91]

In the mid-1920s quantum mechanics was developed to become the standard formulation for atomic physics. In 1923, the French physicist Louis de Broglie put forward his theory of matter waves by stating that particles can exhibit wave characteristics and vice versa. Building on de Broglie's approach, modern quantum mechanics was born in 1925, when the German physicists Werner Heisenberg, Max Born, and Pascual Jordan[92][93] developed matrix mechanics and the Austrian physicist Erwin Schrödinger invented wave mechanics. Born introduced the probabilistic interpretation of Schrödinger's wave function in July 1926.[94] Thus, the entire field of quantum physics emerged, leading to its wider acceptance at the Fifth Solvay Conference in 1927.[95]

By 1930, quantum mechanics had been further unified and formalized by David Hilbert, Paul Dirac and John von Neumann[96] with greater emphasis on measurement, the statistical nature of our knowledge of reality, and philosophical speculation about the 'observer'. It has since permeated many disciplines, including quantum chemistry, quantum electronics, quantum optics, and quantum information science. It also provides a useful framework for many features of the modern periodic table of elements, and describes the behaviors of atoms during chemical bonding and the flow of electrons in computer semiconductors, and therefore plays a crucial role in many modern technologies. While quantum mechanics was constructed to describe the world of the very small, it is also needed to explain some macroscopic phenomena such as superconductors[97] and superfluids.[98]

See also
Bra–ket notation
Einstein's thought experiments
List of textbooks on classical and quantum mechanics
Macroscopic quantum phenomena
Phase-space formulation
Regularization (physics)
Two-state quantum system
Explanatory notes
A momentum eigenstate would be a perfectly monochromatic wave of infinite extent, which is not square-integrable. Likewise, a position eigenstate would be a Dirac delta distribution, not square-integrable and technically not a function at all. Consequently, neither can belong to the particle's Hilbert space. Physicists sometimes introduce fictitious "bases" for a Hilbert space comprising elements outside that space. These are invented for calculational convenience and do not represent physical states.[25]: 100–105 
See, for example, the Feynman Lectures on Physics for some of the technological applications which use quantum mechanics, e.g., transistors (vol III, pp. 14–11 ff), integrated circuits, which are follow-on technology in solid-state physics (vol II, pp. 8–6), and lasers (vol III, pp. 9–13).
See Macroscopic quantum phenomena, Bose–Einstein condensate, and Quantum machine
The published form of the EPR argument was due to Podolsky, and Einstein himself was not satisfied with it. In his own publications and correspondence, Einstein used a different argument to insist that quantum mechanics is an incomplete theory.[60][61][62][63]
References
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Barrett, Jeffrey (2018). "Everett's Relative-State Formulation of Quantum Mechanics". In Zalta, Edward N. (ed.). Stanford Encyclopedia of Philosophy. Metaphysics Research Lab, Stanford University.
Everett, Hugh; Wheeler, J. A.; DeWitt, B. S.; Cooper, L. N.; Van Vechten, D.; Graham, N. (1973). DeWitt, Bryce; Graham, R. Neill (eds.). The Many-Worlds Interpretation of Quantum Mechanics. Princeton Series in Physics. Princeton, NJ: Princeton University Press. p. v. ISBN 0-691-08131-X.
Wallace, David (2003). "Everettian Rationality: defending Deutsch's approach to probability in the Everett interpretation". Stud. Hist. Phil. Mod. Phys. 34 (3): 415–438. arXiv:quant-ph/0303050. Bibcode:2003SHPMP..34..415W. doi:10.1016/S1355-2198(03)00036-4. S2CID 1921913.
Ballentine, L. E. (1973). "Can the statistical postulate of quantum theory be derived? – A critique of the many-universes interpretation". Foundations of Physics. 3 (2): 229–240. Bibcode:1973FoPh....3..229B. doi:10.1007/BF00708440. S2CID 121747282.
Landsman, N. P. (2008). "The Born rule and its interpretation" (PDF). In Weinert, F.; Hentschel, K.; Greenberger, D.; Falkenburg, B. (eds.). Compendium of Quantum Physics. Springer. ISBN 978-3-540-70622-9. The conclusion seems to be that no generally accepted derivation of the Born rule has been given to date, but this does not imply that such a derivation is impossible in principle.
Kent, Adrian (2010). "One world versus many: The inadequacy of Everettian accounts of evolution, probability, and scientific confirmation". In S. Saunders; J. Barrett; A. Kent; D. Wallace (eds.). Many Worlds? Everett, Quantum Theory and Reality. Oxford University Press. arXiv:0905.0624. Bibcode:2009arXiv0905.0624K.
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Feynman, Richard; Leighton, Robert; Sands, Matthew (1964). The Feynman Lectures on Physics. Vol. 1. California Institute of Technology. ISBN 978-0-201-50064-6. Retrieved 30 September 2021.
Martin, Andre (1986), "Cathode Ray Tubes for Industrial and Military Applications", in Hawkes, Peter (ed.), Advances in Electronics and Electron Physics, Volume 67, Academic Press, p. 183, ISBN 978-0-08-057733-3, Evidence for the existence of "cathode-rays" was first found by Plücker and Hittorf ...
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Mehra, J.; Rechenberg, H. (1982). The Historical Development of Quantum Theory, Vol. 1: The Quantum Theory of Planck, Einstein, Bohr and Sommerfeld. Its Foundation and the Rise of Its Difficulties (1900–1925). New York: Springer-Verlag. ISBN 978-0-387-90642-3.
"Quantum – Definition and More". Merriam-Webster Dictionary. Archived from the original on Oct 26, 2012. Retrieved 18 August 2012.
Kuhn, T. S. (1978). Black-body theory and the quantum discontinuity 1894–1912. Oxford: Clarendon Press. ISBN 978-0-19-502383-1.
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Stachel, John (2009). "Bohr and the Photon". Quantum Reality, Relativistic Causality, and Closing the Epistemic Circle. The Western Ontario Series in Philosophy of Science. Vol. 73. Dordrecht: Springer. pp. 69–83. doi:10.1007/978-1-4020-9107-0_5. ISBN 978-1-4020-9106-3.
Einstein, Albert (1905). "Über einen die Erzeugung und Verwandlung des Lichtes betreffenden heuristischen Gesichtspunkt" [On a heuristic point of view concerning the production and transformation of light]. Annalen der Physik. 17 (6): 132–148. Bibcode:1905AnP...322..132E. doi:10.1002/andp.19053220607. Reprinted in Stachel, John, ed. (1989). The Collected Papers of Albert Einstein (in German). Vol. 2. Princeton University Press. pp. 149–166. See also "Einstein's early work on the quantum hypothesis", ibid. pp. 134–148.
Einstein, Albert (1917). "Zur Quantentheorie der Strahlung" [On the Quantum Theory of Radiation]. Physikalische Zeitschrift (in German). 18: 121–128. Bibcode:1917PhyZ...18..121E. Translated in Einstein, A. (1967). "On the Quantum Theory of Radiation". The Old Quantum Theory. Elsevier. pp. 167–183. doi:10.1016/b978-0-08-012102-4.50018-8. ISBN 978-0-08-012102-4.
Ball, Philip (2017-08-31). "A century ago Einstein sparked the notion of the laser". Physics World. Retrieved 2024-03-23.
ter Haar, D. (1967). The Old Quantum Theory. Pergamon Press. pp. 3–75. ISBN 978-0-08-012101-7. LCCN 66-29628.
Bokulich, Alisa; Bokulich, Peter (2020-08-13). "Bohr's Correspondence Principle". In Zalta, Edward N. (ed.). Stanford Encyclopedia of Philosophy.
"Semi-classical approximation". Encyclopedia of Mathematics. Retrieved 1 February 2020.
Sakurai, J. J.; Napolitano, J. (2014). "Quantum Dynamics". Modern Quantum Mechanics. Pearson. ISBN 978-1-292-02410-3. OCLC 929609283.
Aharoni, Amikam (1996). Introduction to the Theory of Ferromagnetism. Clarendon Press. pp. 6–7. ISBN 0-19-851791-2.
David Edwards, "The Mathematical Foundations of Quantum Mechanics", Synthese, Volume 42, Number 1/September, 1979, pp. 1–70.
David Edwards, "The Mathematical Foundations of Quantum Field Theory: Fermions, Gauge Fields, and Super-symmetry, Part I: Lattice Field Theories", International Journal of Theoretical Physics, Vol. 20, No. 7 (1981).
Bernstein, Jeremy (November 2005). "Max Born and the quantum theory". American Journal of Physics. 73 (11): 999–1008. Bibcode:2005AmJPh..73..999B. doi:10.1119/1.2060717. ISSN 0002-9505.
Pais, Abraham (1997). A Tale of Two Continents: A Physicist's Life in a Turbulent World. Princeton, New Jersey: Princeton University Press. ISBN 0-691-01243-1.
Van Hove, Leon (1958). "Von Neumann's contributions to quantum mechanics" (PDF). Bulletin of the American Mathematical Society. 64 (3): Part 2 5–99. doi:10.1090/s0002-9904-1958-10206-2. Archived (PDF) from the original on Jan 20, 2024.
Feynman, Richard. "The Feynman Lectures on Physics Vol. III Ch. 21: The Schrödinger Equation in a Classical Context: A Seminar on Superconductivity, 21-4". California Institute of Technology. Archived from the original on 15 Dec 2016. Retrieved 24 November 2015. ...it was long believed that the wave function of the Schrödinger equation would never have a macroscopic representation analogous to the macroscopic representation of the amplitude for photons. On the other hand, it is now realized that the phenomena of superconductivity presents us with just this situation.
Packard, Richard (2006). "Berkeley Experiments on Superfluid Macroscopic Quantum Effects" (PDF). Physics Department, University of California, Berkeley. Archived from the original (PDF) on 25 November 2015. Retrieved 24 November 2015.
Further reading
The following titles, all by working physicists, attempt to communicate quantum theory to lay people, using a minimum of technical apparatus.

Chester, Marvin (1987). Primer of Quantum Mechanics. John Wiley. ISBN 0-486-42878-8
Cox, Brian; Forshaw, Jeff (2011). The Quantum Universe: Everything That Can Happen Does Happen. Allen Lane. ISBN 978-1-84614-432-5.
Richard Feynman, 1985. QED: The Strange Theory of Light and Matter, Princeton University Press. ISBN 0-691-08388-6. Four elementary lectures on quantum electrodynamics and quantum field theory, yet containing many insights for the expert.
Ghirardi, GianCarlo, 2004. Sneaking a Look at God's Cards, Gerald Malsbary, trans. Princeton Univ. Press. The most technical of the works cited here. Passages using algebra, trigonometry, and bra–ket notation can be passed over on a first reading.
N. David Mermin, 1990, "Spooky actions at a distance: mysteries of the QT" in his Boojums All the Way Through. Cambridge University Press: 110–76.
Victor Stenger, 2000. Timeless Reality: Symmetry, Simplicity, and Multiple Universes. Buffalo, NY: Prometheus Books. Chpts. 5–8. Includes cosmological and philosophical considerations.
More technical:

Bernstein, Jeremy (2009). Quantum Leaps. Cambridge, Massachusetts: Belknap Press of Harvard University Press. ISBN 978-0-674-03541-6.
Bohm, David (1989). Quantum Theory. Dover Publications. ISBN 978-0-486-65969-5.
Binney, James; Skinner, David (2008). The Physics of Quantum Mechanics. Oxford University Press. ISBN 978-0-19-968857-9.
Eisberg, Robert; Resnick, Robert (1985). Quantum Physics of Atoms, Molecules, Solids, Nuclei, and Particles (2nd ed.). Wiley. ISBN 978-0-471-87373-0.
Bryce DeWitt, R. Neill Graham, eds., 1973. The Many-Worlds Interpretation of Quantum Mechanics, Princeton Series in Physics, Princeton University Press. ISBN 0-691-08131-X
Everett, Hugh (1957). "Relative State Formulation of Quantum Mechanics". Reviews of Modern Physics. 29 (3): 454–462. Bibcode:1957RvMP...29..454E. doi:10.1103/RevModPhys.29.454. S2CID 17178479.
Feynman, Richard P.; Leighton, Robert B.; Sands, Matthew (1965). The Feynman Lectures on Physics. Vol. 1–3. Addison-Wesley. ISBN 978-0-7382-0008-8.
D. Greenberger, K. Hentschel, F. Weinert, eds., 2009. Compendium of quantum physics, Concepts, experiments, history and philosophy, Springer-Verlag, Berlin, Heidelberg. Short articles on many QM topics.
Griffiths, David J. (2004). Introduction to Quantum Mechanics (2nd ed.). Prentice Hall. ISBN 978-0-13-111892-8. OCLC 40251748. A standard undergraduate text.
Max Jammer, 1966. The Conceptual Development of Quantum Mechanics. McGraw Hill.
Hagen Kleinert, 2004. Path Integrals in Quantum Mechanics, Statistics, Polymer Physics, and Financial Markets, 3rd ed. Singapore: World Scientific. Draft of 4th edition. Archived 2008-06-15 at the Wayback Machine
L.D. Landau, E.M. Lifshitz (1977). Quantum Mechanics: Non-Relativistic Theory. Vol. 3 (3rd ed.). Pergamon Press. ISBN 978-0-08-020940-1. Online copy
Liboff, Richard L. (2002). Introductory Quantum Mechanics. Addison-Wesley. ISBN 978-0-8053-8714-8.
Gunther Ludwig, 1968. Wave Mechanics. London: Pergamon Press. ISBN 0-08-203204-1
George Mackey (2004). The mathematical foundations of quantum mechanics. Dover Publications. ISBN 0-486-43517-2.
Merzbacher, Eugen (1998). Quantum Mechanics. Wiley, John & Sons, Inc. ISBN 978-0-471-88702-7.
Albert Messiah, 1966. Quantum Mechanics (Vol. I), English translation from French by G.M. Temmer. North Holland, John Wiley & Sons. Cf. chpt. IV, section III. online
Omnès, Roland (1999). Understanding Quantum Mechanics. Princeton University Press. ISBN 978-0-691-00435-8. OCLC 39849482.
Scerri, Eric. R. (2006). The Periodic Table: Its Story and Its Significance. Oxford University Press. ISBN 0-19-530573-6. Considers the extent to which chemistry and the periodic system have been reduced to quantum mechanics.
Schiff, Leonard I. (1955). Quantum Mechanics. Mc-Graw Hill, Inc.
Shankar, R. (1994). Principles of Quantum Mechanics. Springer. ISBN 978-0-306-44790-7.
Stone, A. Douglas (2013). Einstein and the Quantum. Princeton University Press. ISBN 978-0-691-13968-5.
Transnational College of Lex (1996). What is Quantum Mechanics? A Physics Adventure. Language Research Foundation, Boston. ISBN 978-0-9643504-1-0. OCLC 34661512.
Veltman, Martinus J.G. (2003), Facts and Mysteries in Elementary Particle Physics.

to you. But do keep trying. We need the laughs.

would somehow serve to bulwark your previous condensation? (toward OP and other posters)

Oh, MY !!

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Many restaurants do not give pricing online, just glorious descriptions of each item.

Some do not even provide online menus, just delightful artwork, the life story of the founder and chef, and testimonials from customers.

I avoid these places.

i dump any ,repeat any ms nonsense and find great open source prouducts . open office , llebre office and i use a very simple word processer called bean and i have for years

I did have to spring for a proper TV antenna.

I have Libre Office. The free MS Office always limited features. The quality of the product went down with each computer, until I believe it was no longer included in Windows 7?

Anyway, my friends with MS Office can do much more with Excel than I can do with Libre Office sheets and Google sheets.

Very simple bulk edits crash my machine with monotonous regularity.
Complex intermediate calculations also cause problems.
I can usually recover to a very recent keystroke, but I hate having to do so.

I also protect everything I do with a very strong copyright notice, so the AI and other theft tools used by the software can’t benefit from my work without paying me.

These constant come-ons are more than a nuisance. We need to fight back against them.

In booking a room last week online, a message came on the screen that asked if I would like to leave a $20 tip because they had saved me $27 in the booking transaction. I declined.

n/t

...went on the warpath about that recently in his syndicated Car Talk column. IIRC, he was car shopping at a Toyota dealer, and they have apparently started turning car features into a subscription model. Magliozzi was royally pissed.

Everyone feels pressured and pressed from every direction, in every task, every day.

Your biological uniqueness will be added to our collective and you will service us.

Resistance is futile.

ALL software can be deleted or modified.