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{{Modern Physics}}
{{Modern Physics}}


In a literal sense, the term ''modern physics'', means up-to-date physics. In this sense, a significant portion of so-called ''[[classical physics]]'' are modern. However since roughly 1890, new discoveries have caused significant [[paradigm shift]]s; the advent of [[quantum mechanics]] (QM), and of [[Einsteinian relativity]] (ER). Physics that incorporates elements of either quantum mechanics or relativity (or both) are said to be ''modern physics''. In it in this latter sense that the term is generally used.
Gretz smells in a literal sense, the term ''modern physics'', means up-to-date physics. In this sense, a significant portion of so-called ''[[classical physics]]'' are modern. However since roughly 1890, new discoveries have caused significant [[paradigm shift]]s; the advent of [[quantum mechanics]] (QM), and of [[Einsteinian relativity]] (ER). Physics that incorporates elements of either quantum mechanics or relativity (or both) are said to be ''modern physics''. In it in this latter sense that the term is generally used.


Modern physics are often encountered when dealing with extreme conditions. Quantum mechanical effects tend to appear when dealing with "lows" (low temperatures, small distances), while relativistic effects tend to appear when dealing with "highs" (high velocities, large distances), the "middles" being classical behaviour. For example, when analyzing the behavior of a [[gas]] at [[room temperature]], most phenomena will involved the (classical) [[Maxwell–Boltzmann distribution]]. However near [[absolute zero]], the Maxwell–Boltzmann distribution fails to account for the observed behaviour of the gas, and the (modern) [[Fermi–Dirac distribution|Fermi–Dirac]] or [[Bose–Einstein]] distributions have to be used instead.
Modern physics are often encountered when dealing with extreme conditions. Quantum mechanical effects tend to appear when dealing with "lows" (low temperatures, small distances), while relativistic effects tend to appear when dealing with "highs" (high velocities, large distances), the "middles" being classical behaviour. For example, when analyzing the behavior of a [[gas]] at [[room temperature]], most phenomena will involved the (classical) [[Maxwell–Boltzmann distribution]]. However near [[absolute zero]], the Maxwell–Boltzmann distribution fails to account for the observed behaviour of the gas, and the (modern) [[Fermi–Dirac distribution|Fermi–Dirac]] or [[Bose–Einstein]] distributions have to be used instead.

Revision as of 16:33, 10 March 2010

Classical physics is usually concerned with everyday conditions: speeds much lower than the speed of light, and sizes much greater than that of atoms. Modern physics is usually concerned with high velocities and small distances.

The term modern physics refers to the post-Newtonian conception of physics. The term implies that classical descriptions of phenomena are lacking, and that an accurate, "modern", description of reality requires theories to incorporate elements of quantum mechanics or Einsteinian relativity, or both. In general, the term is used to refer to any branch of physics either developed in the early 20th century and onwards, or branches greatly influenced by early 20th century physics.

Modern physics often involves extreme conditions; quantum effects usually involve distances comparable to atoms (roughly 10−9 m), while relativistic effects usually involve velocities comparable to the speed of light (roughly 108 m/s). The small velocities and large distances is usually the realm of classical mechanics.

Overview

Gretz smells in a literal sense, the term modern physics, means up-to-date physics. In this sense, a significant portion of so-called classical physics are modern. However since roughly 1890, new discoveries have caused significant paradigm shifts; the advent of quantum mechanics (QM), and of Einsteinian relativity (ER). Physics that incorporates elements of either quantum mechanics or relativity (or both) are said to be modern physics. In it in this latter sense that the term is generally used.

Modern physics are often encountered when dealing with extreme conditions. Quantum mechanical effects tend to appear when dealing with "lows" (low temperatures, small distances), while relativistic effects tend to appear when dealing with "highs" (high velocities, large distances), the "middles" being classical behaviour. For example, when analyzing the behavior of a gas at room temperature, most phenomena will involved the (classical) Maxwell–Boltzmann distribution. However near absolute zero, the Maxwell–Boltzmann distribution fails to account for the observed behaviour of the gas, and the (modern) Fermi–Dirac or Bose–Einstein distributions have to be used instead.

Very often, it is possible to find – or "retrieve" – the classical behaviour from the modern description by analyzing the modern description at low speeds and large distances (by taking a limit, or by making an approximation). When doing so, the result is called the classical limit.

Classical physics (Rayleigh–Jeans law, black line) failed to explain black body radiation – the so-called ultraviolet catastrophe. The quantum description (Planck's law, colored lines) is said to be modern physics.

The term "modern physics," taken literally, means of course, the sum total of knowledge under the head of present-day physics. In this sense, the physics of 1890 is still modern; very few statements made in a good physics text of 1890 would need to be deleted today as untrue...

On the other hand... there have been enormous advances in physics, and some of these advances have brought into question, or have directly contradicted, certain theories that had seemed to be strongly supported by the experimental evidence.

For example, few, if any physicists in 1890 questioned the wave theory of light. Its triumphs over the old corpuscular theory seemed to be final and complete, particularly after the brilliant experiments of Hertz, in 1887, which demonstrated, beyond doubt, the fundamental soundness of Maxwell's electromagnetic theory of light. And yet... these very experiments of Hertz brought to light a new phenomenon—the photoelectric effect—which played an important part in establishing the quantum theory. The latter theory... is diametrically opposed to the wave theory of light; indeed, the reconciliation of these two theories... was one of the great problems of the first quarter of the twentieth century.

— F.K Richtmyer, E.H. Kennard, T. Lauritsen, Introduction to Modern Physics, 5th edition (1955)[1]

Hallmarks of modern physics

These are generally considered to be the topics regarded as the "core" of the foundation of modern physics:

See also

References

  1. ^ F.K Richtmyer, E.H Kennard, T. Lauristen (1955). Introduction to Modern Physics (5th ed.). New York: McGraw-Hill. p. 1. LCCN 55-0 – 00.{{cite book}}: CS1 maint: multiple names: authors list (link)

Further reading