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#masses — Public Fediverse posts

Live and recent posts from across the Fediverse tagged #masses, aggregated by home.social.

  1. Radio Telescope Array Reveals the Masses of Hidden Young Stars
    atlas.whatip.xyz/post.php?slug
    <p>The Orion Nebula provides a master class in the study of newly born stars as the closest starbirth
    #telescope #reveals #hidden #masses

  2. Radio Telescope Array Reveals the Masses of Hidden Young Stars
    atlas.whatip.xyz/post.php?slug
    <p>The Orion Nebula provides a master class in the study of newly born stars as the closest starbirth
    #telescope #reveals #hidden #masses

  3. A quotation from Cicero

    The people were certain that their freedom was at risk. Their leaders did not agree.
     
    [Populus libertatem agi putabat suam. Dissentiebant principes.]

    Marcus Tullius Cicero (106-43 BC) Roman orator, statesman, philosopher
    Pro Sestio [For Publius Sestius], ch. 48 / sec. 103 (56-02 BC) [tr. @sentantiq (2020)]

    More about (and translations of) this quote: wist.info/cicero-marcus-tulliu…

    #quote #quotes #quotation #qotd #cicero #prosestio #commonpeople #elite #freedom #leadership #liberty #masses #mob #populace

  4. A quotation from Cicero

    The people were certain that their freedom was at risk. Their leaders did not agree.
     
    [Populus libertatem agi putabat suam. Dissentiebant principes.]

    Marcus Tullius Cicero (106-43 BC) Roman orator, statesman, philosopher
    Pro Sestio [For Publius Sestius], ch. 48 / sec. 103 (56-02 BC) [tr. @sentantiq (2020)]

    More about (and translations of) this quote: wist.info/cicero-marcus-tulliu…

    #quote #quotes #quotation #qotd #cicero #prosestio #commonpeople #elite #freedom #leadership #liberty #masses #mob #populace

  5. A quotation from Cicero

    The people were certain that their freedom was at risk. Their leaders did not agree.
     
    [Populus libertatem agi putabat suam. Dissentiebant principes.]

    Marcus Tullius Cicero (106-43 BC) Roman orator, statesman, philosopher
    Pro Sestio [For Publius Sestius], ch. 48 / sec. 103 (56-02 BC) [tr. @sentantiq (2020)]

    More about (and translations of) this quote: wist.info/cicero-marcus-tulliu…

    #quote #quotes #quotation #qotd #cicero #prosestio #commonpeople #elite #freedom #leadership #liberty #masses #mob #populace

  6. A quotation from Cicero

    The people were certain that their freedom was at risk. Their leaders did not agree.
     
    [Populus libertatem agi putabat suam. Dissentiebant principes.]

    Marcus Tullius Cicero (106-43 BC) Roman orator, statesman, philosopher
    Pro Sestio [For Publius Sestius], ch. 48 / sec. 103 (56-02 BC) [tr. @sentantiq (2020)]

    More about (and translations of) this quote: wist.info/cicero-marcus-tulliu…

    #quote #quotes #quotation #qotd #cicero #prosestio #commonpeople #elite #freedom #leadership #liberty #masses #mob #populace

  7. A West Hollywood residency brings a celebrity chocolatier's creations to the masses

    misryoum.com/us/food/a-west-ho

    At first, the large-scale chocolate hearts, bears and gingerbread men could only be found online or in the homes of celebrities like the Kardashians. Then came Butter, Love &amp; Hardwork’s West Hollywood pop-up, and now Chris Ford’s chocolates —...

    #West #Hollywood #residency #brings #celebrity #chocolatiers #creations #the #masses #US_News_Hub #misryoum_com

  8. “This is the most complicated thing that you could possibly imagine,” said Mike Williams, a physicist at the Massachusetts Institute of Technology.

    “In fact, you can’t even imagine how complicated it is.”

    The proton is a quantum mechanical object that exists as a haze of probabilities until an experiment forces it to take a concrete form.

    And its forms differ drastically depending on how researchers set up their experiment.

    Connecting the particle’s many faces has been the work of generations.

    “We’re kind of just starting to understand this system in a complete way,” said Richard Milner, a nuclear physicist at MIT.

    Proof that the proton contains multitudes came from the Stanford Linear Accelerator Center (SLAC) in 1967.

    In earlier experiments, researchers had pelted it with electrons and watched them ricochet off like billiard balls.

    But SLAC could hurl electrons more forcefully,
    and researchers saw that they bounced back differently.

    The electrons were hitting the proton hard enough to shatter it
    — a process called deep inelastic scattering
    — and were rebounding from point-like shards of the proton called quarks.

    “That was the first evidence that quarks actually exist,” said Xiaochao Zheng, a physicist at the University of Virginia.

    After SLAC’s discovery, which won the Nobel Prize in Physics in 1990,
    scrutiny of the proton intensified.

    Physicists have carried out hundreds of scattering experiments to date.

    They infer various aspects of the object’s interior by adjusting how forcefully they bombard it and by choosing which scattered particles they collect in the aftermath.

    Even SLAC’s proton-splitting collisions were gentle by today’s standards.

    In those scattering events, electrons often shot out in ways suggesting that they had crashed into quarks carrying a third of the proton’s total momentum.

    The finding matched a theory from Murray Gell-Mann
    and George Zweig,
    who in 1964 posited that a proton consists of three quarks.

    Gell-Mann and Zweig’s
    “quark model” remains an elegant way to imagine the proton.

    It has two “up” quarks with electric charges of +2/3 each and one “down” quark with a charge of −1/3,
    for a total proton charge of +1.

    But the quark model is an oversimplification that has serious shortcomings.

    It fails, for instance, when it comes to a proton’s #spin,
    a quantum property analogous to angular momentum.

    The proton has half a unit of spin,
    as do each of its up and down quarks.

    Physicists initially supposed that
    — in a calculation echoing the simple charge arithmetic
    — the half-units of the two up quarks minus that of the down quark must equal half a unit for the proton as a whole.

    But in 1988, the European Muon Collaboration reported that the quark spins add up to far less than one-half.

    Similarly, the #masses of two up quarks and one down quark only comprise about 1% of the proton’s total mass.

    These deficits drove home a point physicists were already coming to appreciate:

    The proton is much more than three quarks.

    The Hadron-Electron Ring Accelerator ( #HERA ),
    which operated in Hamburg, Germany, from 1992 to 2007,
    slammed electrons into protons roughly a thousand times more forcefully than SLAC had.

    In HERA experiments, physicists could select electrons that had bounced off of extremely
    low-momentum quarks,
    including ones carrying as little as 0.005% of the proton’s total momentum.

    And detect them they did:
    HERA’s electrons rebounded from a maelstrom of
    low-momentum quarks and their antimatter counterparts, antiquarks

    The results confirmed a sophisticated and outlandish theory that had by then replaced Gell-Mann and Zweig’s quark model.

    Developed in the 1970s, it was a quantum theory of the “strong force” that acts between quarks.

    The theory describes quarks as being roped together by
    force-carrying particles called #gluons.

    Each quark and each gluon has one of three types of “color” charge, labeled red, green and blue;

    these color-charged particles naturally tug on each other and form a group
    — such as a proton
    — whose colors add up to a neutral white.

    The colorful theory became known as #quantum #chromodynamics, or #QCD.

    According to QCD, gluons can pick up momentary spikes of energy.

    With this energy, a gluon splits into a quark and an antiquark
    — each carrying just a tiny bit of momentum
    — before the pair annihilates and disappears.

    It’s this “sea” of transient gluons, quarks and antiquarks that HERA,
    with its greater sensitivity to
    lower-momentum particles,
    detected firsthand.

    HERA also picked up hints of what the proton would look like in more powerful colliders.

    As physicists adjusted HERA to look for lower-momentum quarks,
    these quarks
    — which come from gluons
    — showed up in greater and greater numbers.

    The results suggested that in even higher-energy collisions, the proton would appear as a cloud made up almost entirely of gluons
    quantamagazine.org/inside-the-

  9. “This is the most complicated thing that you could possibly imagine,” said Mike Williams, a physicist at the Massachusetts Institute of Technology.

    “In fact, you can’t even imagine how complicated it is.”

    The proton is a quantum mechanical object that exists as a haze of probabilities until an experiment forces it to take a concrete form.

    And its forms differ drastically depending on how researchers set up their experiment.

    Connecting the particle’s many faces has been the work of generations.

    “We’re kind of just starting to understand this system in a complete way,” said Richard Milner, a nuclear physicist at MIT.

    Proof that the proton contains multitudes came from the Stanford Linear Accelerator Center (SLAC) in 1967.

    In earlier experiments, researchers had pelted it with electrons and watched them ricochet off like billiard balls.

    But SLAC could hurl electrons more forcefully,
    and researchers saw that they bounced back differently.

    The electrons were hitting the proton hard enough to shatter it
    — a process called deep inelastic scattering
    — and were rebounding from point-like shards of the proton called quarks.

    “That was the first evidence that quarks actually exist,” said Xiaochao Zheng, a physicist at the University of Virginia.

    After SLAC’s discovery, which won the Nobel Prize in Physics in 1990,
    scrutiny of the proton intensified.

    Physicists have carried out hundreds of scattering experiments to date.

    They infer various aspects of the object’s interior by adjusting how forcefully they bombard it and by choosing which scattered particles they collect in the aftermath.

    Even SLAC’s proton-splitting collisions were gentle by today’s standards.

    In those scattering events, electrons often shot out in ways suggesting that they had crashed into quarks carrying a third of the proton’s total momentum.

    The finding matched a theory from Murray Gell-Mann
    and George Zweig,
    who in 1964 posited that a proton consists of three quarks.

    Gell-Mann and Zweig’s
    “quark model” remains an elegant way to imagine the proton.

    It has two “up” quarks with electric charges of +2/3 each and one “down” quark with a charge of −1/3,
    for a total proton charge of +1.

    But the quark model is an oversimplification that has serious shortcomings.

    It fails, for instance, when it comes to a proton’s #spin,
    a quantum property analogous to angular momentum.

    The proton has half a unit of spin,
    as do each of its up and down quarks.

    Physicists initially supposed that
    — in a calculation echoing the simple charge arithmetic
    — the half-units of the two up quarks minus that of the down quark must equal half a unit for the proton as a whole.

    But in 1988, the European Muon Collaboration reported that the quark spins add up to far less than one-half.

    Similarly, the #masses of two up quarks and one down quark only comprise about 1% of the proton’s total mass.

    These deficits drove home a point physicists were already coming to appreciate:

    The proton is much more than three quarks.

    The Hadron-Electron Ring Accelerator ( #HERA ),
    which operated in Hamburg, Germany, from 1992 to 2007,
    slammed electrons into protons roughly a thousand times more forcefully than SLAC had.

    In HERA experiments, physicists could select electrons that had bounced off of extremely
    low-momentum quarks,
    including ones carrying as little as 0.005% of the proton’s total momentum.

    And detect them they did:
    HERA’s electrons rebounded from a maelstrom of
    low-momentum quarks and their antimatter counterparts, antiquarks

    The results confirmed a sophisticated and outlandish theory that had by then replaced Gell-Mann and Zweig’s quark model.

    Developed in the 1970s, it was a quantum theory of the “strong force” that acts between quarks.

    The theory describes quarks as being roped together by
    force-carrying particles called #gluons.

    Each quark and each gluon has one of three types of “color” charge, labeled red, green and blue;

    these color-charged particles naturally tug on each other and form a group
    — such as a proton
    — whose colors add up to a neutral white.

    The colorful theory became known as #quantum #chromodynamics, or #QCD.

    According to QCD, gluons can pick up momentary spikes of energy.

    With this energy, a gluon splits into a quark and an antiquark
    — each carrying just a tiny bit of momentum
    — before the pair annihilates and disappears.

    It’s this “sea” of transient gluons, quarks and antiquarks that HERA,
    with its greater sensitivity to
    lower-momentum particles,
    detected firsthand.

    HERA also picked up hints of what the proton would look like in more powerful colliders.

    As physicists adjusted HERA to look for lower-momentum quarks,
    these quarks
    — which come from gluons
    — showed up in greater and greater numbers.

    The results suggested that in even higher-energy collisions, the proton would appear as a cloud made up almost entirely of gluons
    quantamagazine.org/inside-the-

  10. “This is the most complicated thing that you could possibly imagine,” said Mike Williams, a physicist at the Massachusetts Institute of Technology.

    “In fact, you can’t even imagine how complicated it is.”

    The proton is a quantum mechanical object that exists as a haze of probabilities until an experiment forces it to take a concrete form.

    And its forms differ drastically depending on how researchers set up their experiment.

    Connecting the particle’s many faces has been the work of generations.

    “We’re kind of just starting to understand this system in a complete way,” said Richard Milner, a nuclear physicist at MIT.

    Proof that the proton contains multitudes came from the Stanford Linear Accelerator Center (SLAC) in 1967.

    In earlier experiments, researchers had pelted it with electrons and watched them ricochet off like billiard balls.

    But SLAC could hurl electrons more forcefully,
    and researchers saw that they bounced back differently.

    The electrons were hitting the proton hard enough to shatter it
    — a process called deep inelastic scattering
    — and were rebounding from point-like shards of the proton called quarks.

    “That was the first evidence that quarks actually exist,” said Xiaochao Zheng, a physicist at the University of Virginia.

    After SLAC’s discovery, which won the Nobel Prize in Physics in 1990,
    scrutiny of the proton intensified.

    Physicists have carried out hundreds of scattering experiments to date.

    They infer various aspects of the object’s interior by adjusting how forcefully they bombard it and by choosing which scattered particles they collect in the aftermath.

    Even SLAC’s proton-splitting collisions were gentle by today’s standards.

    In those scattering events, electrons often shot out in ways suggesting that they had crashed into quarks carrying a third of the proton’s total momentum.

    The finding matched a theory from Murray Gell-Mann
    and George Zweig,
    who in 1964 posited that a proton consists of three quarks.

    Gell-Mann and Zweig’s
    “quark model” remains an elegant way to imagine the proton.

    It has two “up” quarks with electric charges of +2/3 each and one “down” quark with a charge of −1/3,
    for a total proton charge of +1.

    But the quark model is an oversimplification that has serious shortcomings.

    It fails, for instance, when it comes to a proton’s #spin,
    a quantum property analogous to angular momentum.

    The proton has half a unit of spin,
    as do each of its up and down quarks.

    Physicists initially supposed that
    — in a calculation echoing the simple charge arithmetic
    — the half-units of the two up quarks minus that of the down quark must equal half a unit for the proton as a whole.

    But in 1988, the European Muon Collaboration reported that the quark spins add up to far less than one-half.

    Similarly, the #masses of two up quarks and one down quark only comprise about 1% of the proton’s total mass.

    These deficits drove home a point physicists were already coming to appreciate:

    The proton is much more than three quarks.

    The Hadron-Electron Ring Accelerator ( #HERA ),
    which operated in Hamburg, Germany, from 1992 to 2007,
    slammed electrons into protons roughly a thousand times more forcefully than SLAC had.

    In HERA experiments, physicists could select electrons that had bounced off of extremely
    low-momentum quarks,
    including ones carrying as little as 0.005% of the proton’s total momentum.

    And detect them they did:
    HERA’s electrons rebounded from a maelstrom of
    low-momentum quarks and their antimatter counterparts, antiquarks

    The results confirmed a sophisticated and outlandish theory that had by then replaced Gell-Mann and Zweig’s quark model.

    Developed in the 1970s, it was a quantum theory of the “strong force” that acts between quarks.

    The theory describes quarks as being roped together by
    force-carrying particles called #gluons.

    Each quark and each gluon has one of three types of “color” charge, labeled red, green and blue;

    these color-charged particles naturally tug on each other and form a group
    — such as a proton
    — whose colors add up to a neutral white.

    The colorful theory became known as #quantum #chromodynamics, or #QCD.

    According to QCD, gluons can pick up momentary spikes of energy.

    With this energy, a gluon splits into a quark and an antiquark
    — each carrying just a tiny bit of momentum
    — before the pair annihilates and disappears.

    It’s this “sea” of transient gluons, quarks and antiquarks that HERA,
    with its greater sensitivity to
    lower-momentum particles,
    detected firsthand.

    HERA also picked up hints of what the proton would look like in more powerful colliders.

    As physicists adjusted HERA to look for lower-momentum quarks,
    these quarks
    — which come from gluons
    — showed up in greater and greater numbers.

    The results suggested that in even higher-energy collisions, the proton would appear as a cloud made up almost entirely of gluons
    quantamagazine.org/inside-the-

  11. “This is the most complicated thing that you could possibly imagine,” said Mike Williams, a physicist at the Massachusetts Institute of Technology.

    “In fact, you can’t even imagine how complicated it is.”

    The proton is a quantum mechanical object that exists as a haze of probabilities until an experiment forces it to take a concrete form.

    And its forms differ drastically depending on how researchers set up their experiment.

    Connecting the particle’s many faces has been the work of generations.

    “We’re kind of just starting to understand this system in a complete way,” said Richard Milner, a nuclear physicist at MIT.

    Proof that the proton contains multitudes came from the Stanford Linear Accelerator Center (SLAC) in 1967.

    In earlier experiments, researchers had pelted it with electrons and watched them ricochet off like billiard balls.

    But SLAC could hurl electrons more forcefully,
    and researchers saw that they bounced back differently.

    The electrons were hitting the proton hard enough to shatter it
    — a process called deep inelastic scattering
    — and were rebounding from point-like shards of the proton called quarks.

    “That was the first evidence that quarks actually exist,” said Xiaochao Zheng, a physicist at the University of Virginia.

    After SLAC’s discovery, which won the Nobel Prize in Physics in 1990,
    scrutiny of the proton intensified.

    Physicists have carried out hundreds of scattering experiments to date.

    They infer various aspects of the object’s interior by adjusting how forcefully they bombard it and by choosing which scattered particles they collect in the aftermath.

    Even SLAC’s proton-splitting collisions were gentle by today’s standards.

    In those scattering events, electrons often shot out in ways suggesting that they had crashed into quarks carrying a third of the proton’s total momentum.

    The finding matched a theory from Murray Gell-Mann
    and George Zweig,
    who in 1964 posited that a proton consists of three quarks.

    Gell-Mann and Zweig’s
    “quark model” remains an elegant way to imagine the proton.

    It has two “up” quarks with electric charges of +2/3 each and one “down” quark with a charge of −1/3,
    for a total proton charge of +1.

    But the quark model is an oversimplification that has serious shortcomings.

    It fails, for instance, when it comes to a proton’s #spin,
    a quantum property analogous to angular momentum.

    The proton has half a unit of spin,
    as do each of its up and down quarks.

    Physicists initially supposed that
    — in a calculation echoing the simple charge arithmetic
    — the half-units of the two up quarks minus that of the down quark must equal half a unit for the proton as a whole.

    But in 1988, the European Muon Collaboration reported that the quark spins add up to far less than one-half.

    Similarly, the #masses of two up quarks and one down quark only comprise about 1% of the proton’s total mass.

    These deficits drove home a point physicists were already coming to appreciate:

    The proton is much more than three quarks.

    The Hadron-Electron Ring Accelerator ( #HERA ),
    which operated in Hamburg, Germany, from 1992 to 2007,
    slammed electrons into protons roughly a thousand times more forcefully than SLAC had.

    In HERA experiments, physicists could select electrons that had bounced off of extremely
    low-momentum quarks,
    including ones carrying as little as 0.005% of the proton’s total momentum.

    And detect them they did:
    HERA’s electrons rebounded from a maelstrom of
    low-momentum quarks and their antimatter counterparts, antiquarks

    The results confirmed a sophisticated and outlandish theory that had by then replaced Gell-Mann and Zweig’s quark model.

    Developed in the 1970s, it was a quantum theory of the “strong force” that acts between quarks.

    The theory describes quarks as being roped together by
    force-carrying particles called #gluons.

    Each quark and each gluon has one of three types of “color” charge, labeled red, green and blue;

    these color-charged particles naturally tug on each other and form a group
    — such as a proton
    — whose colors add up to a neutral white.

    The colorful theory became known as #quantum #chromodynamics, or #QCD.

    According to QCD, gluons can pick up momentary spikes of energy.

    With this energy, a gluon splits into a quark and an antiquark
    — each carrying just a tiny bit of momentum
    — before the pair annihilates and disappears.

    It’s this “sea” of transient gluons, quarks and antiquarks that HERA,
    with its greater sensitivity to
    lower-momentum particles,
    detected firsthand.

    HERA also picked up hints of what the proton would look like in more powerful colliders.

    As physicists adjusted HERA to look for lower-momentum quarks,
    these quarks
    — which come from gluons
    — showed up in greater and greater numbers.

    The results suggested that in even higher-energy collisions, the proton would appear as a cloud made up almost entirely of gluons
    quantamagazine.org/inside-the-

  12. “This is the most complicated thing that you could possibly imagine,” said Mike Williams, a physicist at the Massachusetts Institute of Technology.

    “In fact, you can’t even imagine how complicated it is.”

    The proton is a quantum mechanical object that exists as a haze of probabilities until an experiment forces it to take a concrete form.

    And its forms differ drastically depending on how researchers set up their experiment.

    Connecting the particle’s many faces has been the work of generations.

    “We’re kind of just starting to understand this system in a complete way,” said Richard Milner, a nuclear physicist at MIT.

    Proof that the proton contains multitudes came from the Stanford Linear Accelerator Center (SLAC) in 1967.

    In earlier experiments, researchers had pelted it with electrons and watched them ricochet off like billiard balls.

    But SLAC could hurl electrons more forcefully,
    and researchers saw that they bounced back differently.

    The electrons were hitting the proton hard enough to shatter it
    — a process called deep inelastic scattering
    — and were rebounding from point-like shards of the proton called quarks.

    “That was the first evidence that quarks actually exist,” said Xiaochao Zheng, a physicist at the University of Virginia.

    After SLAC’s discovery, which won the Nobel Prize in Physics in 1990,
    scrutiny of the proton intensified.

    Physicists have carried out hundreds of scattering experiments to date.

    They infer various aspects of the object’s interior by adjusting how forcefully they bombard it and by choosing which scattered particles they collect in the aftermath.

    Even SLAC’s proton-splitting collisions were gentle by today’s standards.

    In those scattering events, electrons often shot out in ways suggesting that they had crashed into quarks carrying a third of the proton’s total momentum.

    The finding matched a theory from Murray Gell-Mann
    and George Zweig,
    who in 1964 posited that a proton consists of three quarks.

    Gell-Mann and Zweig’s
    “quark model” remains an elegant way to imagine the proton.

    It has two “up” quarks with electric charges of +2/3 each and one “down” quark with a charge of −1/3,
    for a total proton charge of +1.

    But the quark model is an oversimplification that has serious shortcomings.

    It fails, for instance, when it comes to a proton’s #spin,
    a quantum property analogous to angular momentum.

    The proton has half a unit of spin,
    as do each of its up and down quarks.

    Physicists initially supposed that
    — in a calculation echoing the simple charge arithmetic
    — the half-units of the two up quarks minus that of the down quark must equal half a unit for the proton as a whole.

    But in 1988, the European Muon Collaboration reported that the quark spins add up to far less than one-half.

    Similarly, the #masses of two up quarks and one down quark only comprise about 1% of the proton’s total mass.

    These deficits drove home a point physicists were already coming to appreciate:

    The proton is much more than three quarks.

    The Hadron-Electron Ring Accelerator ( #HERA ),
    which operated in Hamburg, Germany, from 1992 to 2007,
    slammed electrons into protons roughly a thousand times more forcefully than SLAC had.

    In HERA experiments, physicists could select electrons that had bounced off of extremely
    low-momentum quarks,
    including ones carrying as little as 0.005% of the proton’s total momentum.

    And detect them they did:
    HERA’s electrons rebounded from a maelstrom of
    low-momentum quarks and their antimatter counterparts, antiquarks

    The results confirmed a sophisticated and outlandish theory that had by then replaced Gell-Mann and Zweig’s quark model.

    Developed in the 1970s, it was a quantum theory of the “strong force” that acts between quarks.

    The theory describes quarks as being roped together by
    force-carrying particles called #gluons.

    Each quark and each gluon has one of three types of “color” charge, labeled red, green and blue;

    these color-charged particles naturally tug on each other and form a group
    — such as a proton
    — whose colors add up to a neutral white.

    The colorful theory became known as #quantum #chromodynamics, or #QCD.

    According to QCD, gluons can pick up momentary spikes of energy.

    With this energy, a gluon splits into a quark and an antiquark
    — each carrying just a tiny bit of momentum
    — before the pair annihilates and disappears.

    It’s this “sea” of transient gluons, quarks and antiquarks that HERA,
    with its greater sensitivity to
    lower-momentum particles,
    detected firsthand.

    HERA also picked up hints of what the proton would look like in more powerful colliders.

    As physicists adjusted HERA to look for lower-momentum quarks,
    these quarks
    — which come from gluons
    — showed up in greater and greater numbers.

    The results suggested that in even higher-energy collisions, the proton would appear as a cloud made up almost entirely of gluons
    quantamagazine.org/inside-the-

  13. 📉 Ah, the endless saga of elites herding the #masses like sheep, now with the magical aid of AI persuasion! 🎩🤖 Who knew that reducing costs meant increasing the #manipulation of society—an economist's wet dream come true! 🌪️
    arxiv.org/abs/2512.04047 #elitesherding #AIpersuasion #economics #HackerNews #ngated

  14. 📉 Ah, the endless saga of elites herding the #masses like sheep, now with the magical aid of AI persuasion! 🎩🤖 Who knew that reducing costs meant increasing the #manipulation of society—an economist's wet dream come true! 🌪️
    arxiv.org/abs/2512.04047 #elitesherding #AIpersuasion #economics #HackerNews #ngated

  15. 📉 Ah, the endless saga of elites herding the #masses like sheep, now with the magical aid of AI persuasion! 🎩🤖 Who knew that reducing costs meant increasing the #manipulation of society—an economist's wet dream come true! 🌪️
    arxiv.org/abs/2512.04047 #elitesherding #AIpersuasion #economics #HackerNews #ngated

  16. 📉 Ah, the endless saga of elites herding the #masses like sheep, now with the magical aid of AI persuasion! 🎩🤖 Who knew that reducing costs meant increasing the #manipulation of society—an economist's wet dream come true! 🌪️
    arxiv.org/abs/2512.04047 #elitesherding #AIpersuasion #economics #HackerNews #ngated

  17. A quotation from Charles Mackay

    Men, it has been well said, think in herds; it will be seen that they go mad in herds, while they only recover their senses slowly, and one by one.

    Charles Mackay (1814-1889) Scottish poet, journalist, song writer
    Memoirs of Extraordinary Popular Delusions and the Madness of Crowds, Preface (1841)

    More info about this quote: wist.info/mackay-charles/78848…

    #quote #quotes #quotation #qotd #charlesmackay #herd #humannature #humanity #madness #masshysteria #masses #mob

  18. A quotation from Charles Mackay

    Men, it has been well said, think in herds; it will be seen that they go mad in herds, while they only recover their senses slowly, and one by one.

    Charles Mackay (1814-1889) Scottish poet, journalist, song writer
    Memoirs of Extraordinary Popular Delusions and the Madness of Crowds, Preface (1841)

    More info about this quote: wist.info/mackay-charles/78848…

    #quote #quotes #quotation #qotd #charlesmackay #herd #humannature #humanity #madness #masshysteria #masses #mob

  19. A quotation from Charles Mackay

    Men, it has been well said, think in herds; it will be seen that they go mad in herds, while they only recover their senses slowly, and one by one.

    Charles Mackay (1814-1889) Scottish poet, journalist, song writer
    Memoirs of Extraordinary Popular Delusions and the Madness of Crowds, Preface (1841)

    More info about this quote: wist.info/mackay-charles/78848…

    #quote #quotes #quotation #qotd #charlesmackay #herd #humannature #humanity #madness #masshysteria #masses #mob

  20. A quotation from Charles Mackay

    Men, it has been well said, think in herds; it will be seen that they go mad in herds, while they only recover their senses slowly, and one by one.

    Charles Mackay (1814-1889) Scottish poet, journalist, song writer
    Memoirs of Extraordinary Popular Delusions and the Madness of Crowds, Preface (1841)

    More info about this quote: wist.info/mackay-charles/78848…

    #quote #quotes #quotation #qotd #charlesmackay #herd #humannature #humanity #madness #masshysteria #masses #mob

  21. A quotation from Oliver Wendell Holmes, Sr.

    The boldest thinker may have his moments of languor and discouragement, when he feels as if he could willingly exchange faiths with the old beldame crossing herself at the cathedral-door, — nay, that, if he could drop all coherent thought, and lie in the flowery meadow with the brown-eyed solemnly unthinking cattle, looking up to the sky, and all their simple consciousness staining itself blue, then down to the grass, and life turning to a mere greenness, blended with confused scents of herbs, — no individual mind-movement such as men are teased with, but the great calm cattle-sense of all time and all places that know the milky smell of herds, — if he could be like these, he would be content to be driven home by the cow-boy, and share the grassy banquet of the king of ancient Babylon. Let us be very generous, then, in our judgment of those who leave the front ranks of thought for the company of the meek non-combatants who follow with the baggage and provisions. Age, illness, too much wear and tear, a half-formed paralysis, may bring any of us to this pass.

    Oliver Wendell Holmes, Sr. (1809-1894) American poet, essayist, scholar
    Article (1860-09), “The Professor’s Story [Elsie Venner],” ch. 18, Atlantic Monthly, Vol. 6, No. 35

    More info about this quote: wist.info/holmes-sr-oliver-wen…

    #quote #quotes #quotation #qotd #fatigue #acceptance #cattle #contentment #discouragement #faith #follower #following #givingup #intelligence #masses #orthodoxy #sloth #thinker #thinking #simplicity #intellect #goingalong

  22. A quotation from Oliver Wendell Holmes, Sr.

    The boldest thinker may have his moments of languor and discouragement, when he feels as if he could willingly exchange faiths with the old beldame crossing herself at the cathedral-door, — nay, that, if he could drop all coherent thought, and lie in the flowery meadow with the brown-eyed solemnly unthinking cattle, looking up to the sky, and all their simple consciousness staining itself blue, then down to the grass, and life turning to a mere greenness, blended with confused scents of herbs, — no individual mind-movement such as men are teased with, but the great calm cattle-sense of all time and all places that know the milky smell of herds, — if he could be like these, he would be content to be driven home by the cow-boy, and share the grassy banquet of the king of ancient Babylon. Let us be very generous, then, in our judgment of those who leave the front ranks of thought for the company of the meek non-combatants who follow with the baggage and provisions. Age, illness, too much wear and tear, a half-formed paralysis, may bring any of us to this pass.

    Oliver Wendell Holmes, Sr. (1809-1894) American poet, essayist, scholar
    Article (1860-09), “The Professor’s Story [Elsie Venner],” ch. 18, Atlantic Monthly, Vol. 6, No. 35

    More info about this quote: wist.info/holmes-sr-oliver-wen…

    #quote #quotes #quotation #qotd #fatigue #acceptance #cattle #contentment #discouragement #faith #follower #following #givingup #intelligence #masses #orthodoxy #sloth #thinker #thinking #simplicity #intellect #goingalong

  23. A quotation from Oliver Wendell Holmes, Sr.

    The boldest thinker may have his moments of languor and discouragement, when he feels as if he could willingly exchange faiths with the old beldame crossing herself at the cathedral-door, — nay, that, if he could drop all coherent thought, and lie in the flowery meadow with the brown-eyed solemnly unthinking cattle, looking up to the sky, and all their simple consciousness staining itself blue, then down to the grass, and life turning to a mere greenness, blended with confused scents of herbs, — no individual mind-movement such as men are teased with, but the great calm cattle-sense of all time and all places that know the milky smell of herds, — if he could be like these, he would be content to be driven home by the cow-boy, and share the grassy banquet of the king of ancient Babylon. Let us be very generous, then, in our judgment of those who leave the front ranks of thought for the company of the meek non-combatants who follow with the baggage and provisions. Age, illness, too much wear and tear, a half-formed paralysis, may bring any of us to this pass.

    Oliver Wendell Holmes, Sr. (1809-1894) American poet, essayist, scholar
    Article (1860-09), “The Professor’s Story [Elsie Venner],” ch. 18, Atlantic Monthly, Vol. 6, No. 35

    More info about this quote: wist.info/holmes-sr-oliver-wen…

    #quote #quotes #quotation #qotd #fatigue #acceptance #cattle #contentment #discouragement #faith #follower #following #givingup #intelligence #masses #orthodoxy #sloth #thinker #thinking #simplicity #intellect #goingalong

  24. A quotation from Oliver Wendell Holmes, Sr.

    The boldest thinker may have his moments of languor and discouragement, when he feels as if he could willingly exchange faiths with the old beldame crossing herself at the cathedral-door, — nay, that, if he could drop all coherent thought, and lie in the flowery meadow with the brown-eyed solemnly unthinking cattle, looking up to the sky, and all their simple consciousness staining itself blue, then down to the grass, and life turning to a mere greenness, blended with confused scents of herbs, — no individual mind-movement such as men are teased with, but the great calm cattle-sense of all time and all places that know the milky smell of herds, — if he could be like these, he would be content to be driven home by the cow-boy, and share the grassy banquet of the king of ancient Babylon. Let us be very generous, then, in our judgment of those who leave the front ranks of thought for the company of the meek non-combatants who follow with the baggage and provisions. Age, illness, too much wear and tear, a half-formed paralysis, may bring any of us to this pass.

    Oliver Wendell Holmes, Sr. (1809-1894) American poet, essayist, scholar
    Article (1860-09), “The Professor’s Story [Elsie Venner],” ch. 18, Atlantic Monthly, Vol. 6, No. 35

    More info about this quote: wist.info/holmes-sr-oliver-wen…

    #quote #quotes #quotation #qotd #fatigue #acceptance #cattle #contentment #discouragement #faith #follower #following #givingup #intelligence #masses #orthodoxy #sloth #thinker #thinking #simplicity #intellect #goingalong

  25. A quotation from Charles Mackay

    Every age has its peculiar folly; some scheme, project, or phantasy into which it plunges, spurred on either by the love of gain, the necessity of excitement, or the mere force of imitation. Failing in these, it has some madness, to which it is goaded by political or religious causes, or both combined.

    Charles Mackay (1814-1889) Scottish poet, journalist, song writer
    Memoirs of Extraordinary Popular Delusions and the Madness of Crowds, “The Crusades” (1841)

    More info about this quote: wist.info/mackay-charles/78827…

    #quote #quotes #quotation #qotd #charlesmackay #craziness #delusion #era #fad #frenzy #history #humannature #madness #masshysteria #masses #craze

  26. A quotation from Charles Mackay

    Every age has its peculiar folly; some scheme, project, or phantasy into which it plunges, spurred on either by the love of gain, the necessity of excitement, or the mere force of imitation. Failing in these, it has some madness, to which it is goaded by political or religious causes, or both combined.

    Charles Mackay (1814-1889) Scottish poet, journalist, song writer
    Memoirs of Extraordinary Popular Delusions and the Madness of Crowds, “The Crusades” (1841)

    More info about this quote: wist.info/mackay-charles/78827…

    #quote #quotes #quotation #qotd #charlesmackay #craziness #delusion #era #fad #frenzy #history #humannature #madness #masshysteria #masses #craze

  27. A quotation from Charles Mackay

    Every age has its peculiar folly; some scheme, project, or phantasy into which it plunges, spurred on either by the love of gain, the necessity of excitement, or the mere force of imitation. Failing in these, it has some madness, to which it is goaded by political or religious causes, or both combined.

    Charles Mackay (1814-1889) Scottish poet, journalist, song writer
    Memoirs of Extraordinary Popular Delusions and the Madness of Crowds, “The Crusades” (1841)

    More info about this quote: wist.info/mackay-charles/78827…

    #quote #quotes #quotation #qotd #charlesmackay #craziness #delusion #era #fad #frenzy #history #humannature #madness #masshysteria #masses #craze

  28. A quotation from Charles Mackay

    Every age has its peculiar folly; some scheme, project, or phantasy into which it plunges, spurred on either by the love of gain, the necessity of excitement, or the mere force of imitation. Failing in these, it has some madness, to which it is goaded by political or religious causes, or both combined.

    Charles Mackay (1814-1889) Scottish poet, journalist, song writer
    Memoirs of Extraordinary Popular Delusions and the Madness of Crowds, “The Crusades” (1841)

    More info about this quote: wist.info/mackay-charles/78827…

    #quote #quotes #quotation #qotd #charlesmackay #craziness #delusion #era #fad #frenzy #history #humannature #madness #masshysteria #masses #craze

  29. 2 " ... and at their expense, all the way to their #death, #sacrifice, and #massacre, and yet the #masses want it, they want this #power to be exercised" - attributed to Michel #Foucault in the paper From #Microfascism to Joyful Affects: A Posthuman Approach to #SocialMedia Redesign ... 🧵

  30. 2 " ... and at their expense, all the way to their #death, #sacrifice, and #massacre, and yet the #masses want it, they want this #power to be exercised" - attributed to Michel #Foucault in the paper From #Microfascism to Joyful Affects: A Posthuman Approach to #SocialMedia Redesign ... 🧵

  31. A quotation from Montaigne

    The man who makes it his business to please the multitude is never done.

    Michel de Montaigne (1533-1592) French essayist
    The Autobiography of Michel de Montaigne, ch. 34 [ed. Marven Lowenthal (1935)]

    Sourcing, notes: wist.info/montaigne-michel-de/…

    #quote #quotes #quotation #qotd #montaigne #entertain #masses #pleaseeveryone #publicopinion #fickleness

  32. A quotation from Montaigne

    The man who makes it his business to please the multitude is never done.

    Michel de Montaigne (1533-1592) French essayist
    The Autobiography of Michel de Montaigne, ch. 34 [ed. Marven Lowenthal (1935)]

    Sourcing, notes: wist.info/montaigne-michel-de/…

    #quote #quotes #quotation #qotd #montaigne #entertain #masses #pleaseeveryone #publicopinion #fickleness

  33. A quotation from Montaigne

    The man who makes it his business to please the multitude is never done.

    Michel de Montaigne (1533-1592) French essayist
    The Autobiography of Michel de Montaigne, ch. 34 [ed. Marven Lowenthal (1935)]

    Sourcing, notes: wist.info/montaigne-michel-de/…

    #quote #quotes #quotation #qotd #montaigne #entertain #masses #pleaseeveryone #publicopinion #fickleness

  34. A quotation from Montaigne

    The man who makes it his business to please the multitude is never done.

    Michel de Montaigne (1533-1592) French essayist
    The Autobiography of Michel de Montaigne, ch. 34 [ed. Marven Lowenthal (1935)]

    Sourcing, notes: wist.info/montaigne-michel-de/…

    #quote #quotes #quotation #qotd #montaigne #entertain #masses #pleaseeveryone #publicopinion #fickleness

  35. Many #recycling programs are a farce. Every #recycler has a huge list of wants/don't wants. The little triangles on things are.....wtf? It's TOO #COMPLICATED for the #masses. Fuck recycling.

    #Biodegradable materials are where it's at. People are lazy. The solution MUST also be #lazy. If the general public need to think, they won't do it. That's why we have an orange clown taking a wrecking ball to the #planet.

  36. A quotation from Cicero

    He won over the ignorant masses with shows, building projects, largesses, and banquets. His followers he bound to him by rewards, his opponents by an apparent clemency. In short, he succeeded in bringing a free country, partly because of its fear, partly because of its passivity, to an acceptance of servitude.
     
    [Muneribus, monumentis, congiariis, epulis multitudinem imperitam delenierat; suos praemiis, adversarios clementiae specie devinxerat. Quid multa? Attulerat iam liberae civitati partim metu partim patientia consuetudinem serviendi.]

    Marcus Tullius Cicero (106-43 BC) Roman orator, statesman, philosopher
    Philippics [Philippicae; Antonian Orations], No. 2, ch. 45 / sec. 116 (2.45/2.116) (44-10-24 BC) [tr. Berry (2006)]

    Sourcing, notes, other translations: wist.info/cicero-marcus-tulliu…

    #quote #quotes #quotation #qotd #cicero #juliuscaesar #acquiescence #breadandcircuses #freedom #masses #passivity #politicalpower #populace #power #rewards #servitude

  37. A quotation from Cicero

    He won over the ignorant masses with shows, building projects, largesses, and banquets. His followers he bound to him by rewards, his opponents by an apparent clemency. In short, he succeeded in bringing a free country, partly because of its fear, partly because of its passivity, to an acceptance of servitude.
     
    [Muneribus, monumentis, congiariis, epulis multitudinem imperitam delenierat; suos praemiis, adversarios clementiae specie devinxerat. Quid multa? Attulerat iam liberae civitati partim metu partim patientia consuetudinem serviendi.]

    Marcus Tullius Cicero (106-43 BC) Roman orator, statesman, philosopher
    Philippics [Philippicae; Antonian Orations], No. 2, ch. 45 / sec. 116 (2.45/2.116) (44-10-24 BC) [tr. Berry (2006)]

    Sourcing, notes, other translations: wist.info/cicero-marcus-tulliu…

    #quote #quotes #quotation #qotd #cicero #juliuscaesar #acquiescence #breadandcircuses #freedom #masses #passivity #politicalpower #populace #power #rewards #servitude

  38. A quotation from Cicero

    He won over the ignorant masses with shows, building projects, largesses, and banquets. His followers he bound to him by rewards, his opponents by an apparent clemency. In short, he succeeded in bringing a free country, partly because of its fear, partly because of its passivity, to an acceptance of servitude.
     
    [Muneribus, monumentis, congiariis, epulis multitudinem imperitam delenierat; suos praemiis, adversarios clementiae specie devinxerat. Quid multa? Attulerat iam liberae civitati partim metu partim patientia consuetudinem serviendi.]

    Marcus Tullius Cicero (106-43 BC) Roman orator, statesman, philosopher
    Philippics [Philippicae; Antonian Orations], No. 2, ch. 45 / sec. 116 (2.45/2.116) (44-10-24 BC) [tr. Berry (2006)]

    Sourcing, notes, other translations: wist.info/cicero-marcus-tulliu…

    #quote #quotes #quotation #qotd #cicero #juliuscaesar #acquiescence #breadandcircuses #freedom #masses #passivity #politicalpower #populace #power #rewards #servitude

  39. A quotation from Orwell

    In each great revolutionary struggle the masses are led on by vague dreams of human brotherhood, and then, when the new ruling class is well established in power, they are thrust back into servitude. This is practically the whole of political history, as Burnham sees it. […] History consists of a series of swindles, in which the masses are first lured into revolt by the promise of Utopia, and then, when they have done their job, enslaved over again by the new masters.

    George Orwell (1903-1950) English writer [pseud. of Eric Arthur Blair]
    Essay (1946-05), “Second Thoughts on James Burnham,” Polemic Magazine

    Sourcing, notes: wist.info/orwell-george/14826/

    #quote #quotes #quotation #qotd #orwell #georgeorwell #classwarfare #commonpeople #history #masses #oligarchy #revolution #rulers #rulingclass

  40. A quotation from Orwell

    In each great revolutionary struggle the masses are led on by vague dreams of human brotherhood, and then, when the new ruling class is well established in power, they are thrust back into servitude. This is practically the whole of political history, as Burnham sees it. […] History consists of a series of swindles, in which the masses are first lured into revolt by the promise of Utopia, and then, when they have done their job, enslaved over again by the new masters.

    George Orwell (1903-1950) English writer [pseud. of Eric Arthur Blair]
    Essay (1946-05), “Second Thoughts on James Burnham,” Polemic Magazine

    Sourcing, notes: wist.info/orwell-george/14826/

    #quote #quotes #quotation #qotd #orwell #georgeorwell #classwarfare #commonpeople #history #masses #oligarchy #revolution #rulers #rulingclass

  41. A quotation from Orwell

    In each great revolutionary struggle the masses are led on by vague dreams of human brotherhood, and then, when the new ruling class is well established in power, they are thrust back into servitude. This is practically the whole of political history, as Burnham sees it. […] History consists of a series of swindles, in which the masses are first lured into revolt by the promise of Utopia, and then, when they have done their job, enslaved over again by the new masters.

    George Orwell (1903-1950) English writer [pseud. of Eric Arthur Blair]
    Essay (1946-05), “Second Thoughts on James Burnham,” Polemic Magazine

    Sourcing, notes: wist.info/orwell-george/14826/

    #quote #quotes #quotation #qotd #orwell #georgeorwell #classwarfare #commonpeople #history #masses #oligarchy #revolution #rulers #rulingclass

  42. In today's episode of "Math #Mystifies #the #Masses," we dive into the riveting world of #probability #density #functions and #interpolation factors—because apparently, nothing screams excitement like calculating how an "entropy bulge" curves upward. 📈🤯 Spoiler alert: It's concave! Stay tuned for more edge-of-your-seat #algebraic #adventures. 🙄
    cgad.ski/blog/entropy-of-a-mix #Math #Factors #Entropy #Bulge #HackerNews #ngated

  43. In today's episode of "Math #Mystifies #the #Masses," we dive into the riveting world of #probability #density #functions and #interpolation factors—because apparently, nothing screams excitement like calculating how an "entropy bulge" curves upward. 📈🤯 Spoiler alert: It's concave! Stay tuned for more edge-of-your-seat #algebraic #adventures. 🙄
    cgad.ski/blog/entropy-of-a-mix #Math #Factors #Entropy #Bulge #HackerNews #ngated

  44. In today's episode of "Math #Mystifies #the #Masses," we dive into the riveting world of #probability #density #functions and #interpolation factors—because apparently, nothing screams excitement like calculating how an "entropy bulge" curves upward. 📈🤯 Spoiler alert: It's concave! Stay tuned for more edge-of-your-seat #algebraic #adventures. 🙄
    cgad.ski/blog/entropy-of-a-mix #Math #Factors #Entropy #Bulge #HackerNews #ngated

  45. In today's episode of "Math #Mystifies #the #Masses," we dive into the riveting world of #probability #density #functions and #interpolation factors—because apparently, nothing screams excitement like calculating how an "entropy bulge" curves upward. 📈🤯 Spoiler alert: It's concave! Stay tuned for more edge-of-your-seat #algebraic #adventures. 🙄
    cgad.ski/blog/entropy-of-a-mix #Math #Factors #Entropy #Bulge #HackerNews #ngated