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Spherical and Cylindrical Capacitor01:26

Spherical and Cylindrical Capacitor

A spherical capacitor consists of two concentric conducting spherical shells of radii R1 (inner shell) and R2 (outer shell). The shells have equal and opposite charges of +Q and −Q, respectively. For an isolated conducting spherical capacitor, the radius of the outer shell can be considered to be infinite.
Conventionally, considering the symmetry, the electric field between the concentric shells of a spherical capacitor is directed radially outward. The magnitude of the field, calculated by...
Energy Stored in a Capacitor01:12

Energy Stored in a Capacitor

When an archer pulls the string in a bow, he saves the work done in the form of elastic potential energy. When he releases the string, the potential energy is released as kinetic energy of the arrow. A capacitor works on the same principle in which the work done is saved as electric potential energy. The potential energy (UC) could be calculated by measuring the work done (W) to charge the capacitor.
Van de Graaff Generator01:15

Van de Graaff Generator

Van de Graaff generators (or Van de Graaffs) are devices used to demonstrate high voltage due to static electricity that can also be used for research. Robert Van de Graaff first built one in 1931 (based on original suggestions by Lord Kelvin) for use in nuclear physics research.
Van de Graaff uses both smooth and pointed surfaces, conductors, and insulators to generate large static charges and, hence, large voltages. A substantial excess charge can be deposited on the sphere because it moves...
Energy Stored in Capacitors01:10

Energy Stored in Capacitors

A parallel plate capacitor, when connected to a battery, develops a potential difference across its plates. This potential difference is key to the operation of the capacitor, as it determines how much electrical energy the capacitor can store.
By integrating the equation that relates voltage and current in a capacitor, one can derive an equation for the voltage across the capacitor at any given time. This equation is crucial in understanding and predicting the behavior of capacitors in...
Energy Stored in a Capacitor: Problem Solving01:26

Energy Stored in a Capacitor: Problem Solving

In 1749, Benjamin Franklin coined the word battery for a series of capacitors connected to store energy. Capacitors store electric potential energy that can be released over a short time. This property means capacitors have a wide range of applications.
Capacitor-discharge ignition is a type of ignition system commonly found in small engines where the energy released from a capacitor ignites an induction coil that, in turn, fires the spark plug.
To calculate the energy stored in a capacitor of...
Transmission Electron Microscopy01:15

Transmission Electron Microscopy

In 1931, physicist Ernst Ruska—building on the idea that magnetic fields can direct an electron beam just as lenses can direct a beam of light in an optical microscope—developed the first prototype of the electron microscope. This development led to the development of the field of electron microscopy. In the transmission electron microscope (TEM), electrons are produced by a hot tungsten element and accelerated by a potential difference in an electron gun, which gives them up to 400 keV in...

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Related Experiment Video

Updated: May 11, 2026

Direct Imaging of Laser-driven Ultrafast Molecular Rotation
10:52

Direct Imaging of Laser-driven Ultrafast Molecular Rotation

Published on: February 4, 2017

Temporal and lateral electron pulse compression by a compact spherical electrostatic capacitor.

Krzysztof P Grzelakowski1, Rudolf M Tromp

  • 1OPTICON Nanotechnology, Muchoborska 18, PL54-424 Wrocław, Poland. kgrzelakowski@op.pl

Ultramicroscopy
|May 22, 2013
PubMed
Summary
This summary is machine-generated.

A novel spherical deflector analyzer achieves femtosecond electron pulse compression by reversing electron pulse time. This method minimizes aberrations for ultra-short electron pulses, limited only by system imperfections.

Keywords:
4D diffraction4D microscopyDTEMElectron pulse compressionUED

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Last Updated: May 11, 2026

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External Excitation of Neurons Using Electric and Magnetic Fields in One- and Two-dimensional Cultures
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Published on: July 2, 2012

Area of Science:

  • Physics
  • Accelerator Physics
  • Electron Optics

Background:

  • High intensity electron pulses are crucial for various scientific applications.
  • Achieving femtosecond electron pulse compression in both space and time presents significant challenges.
  • Existing methods often struggle with aberrations and limitations in pulse duration.

Purpose of the Study:

  • To propose and demonstrate a novel method for femtosecond electron pulse compression.
  • To utilize the unique properties of a spherical electrostatic capacitor for pulse manipulation.
  • To achieve aberration-free time reversal and compression of electron pulses.

Main Methods:

  • Development of the alpha-Spherical Deflector Analyzer (α-SDA) with 2π total deflection.
  • Leveraging the central-force electrostatic field of a spherical electrostatic capacitor.
  • Exploiting the mirror symmetry at π deflection for aberration cancellation and time reversal.

Main Results:

  • The α-SDA enables practical realization of femtosecond electron pulse compression.
  • Mirror symmetry at π deflection leads to aberration-free time reversal.
  • Time-divergent electrons are transformed into a time-convergent pulse at the output.
  • Extremely short electron pulses are achieved, limited by laser pulse duration and electron beam emittance.

Conclusions:

  • The proposed α-SDA offers a novel and effective solution for electron pulse compression.
  • The system achieves aberration-free time reversal, crucial for ultra-short pulse generation.
  • This technique has the potential to significantly advance research requiring high-intensity, femtosecond electron pulses.