phenomenal field

(noun)

Our subjective reality, all that we are aware of, including objects and people as well as our behaviors, thoughts, images, and ideas.

Related Terms

Examples of phenomenal field in the following topics:

  • Rogers' Humanistic Theory of Personality

    • Rogers advanced the field by stressing that the human person is an active, creative, experiencing being who lives in the present and subjectively responds to current perceptions, relationships, and encounters.
    • A person reacts to changes in their phenomenal field, which includes external objects and people as well as internal thoughts and emotions.
    • The phenomenal field refers to a person's subjective reality, which includes external objects and people as well as internal thoughts and emotions.
    • The person's motivations and environments both act on their phenomenal field.

  • Evaluating the Humanistic Perspective on Personality

    • Personality development is thought to be based on interactions in the phenomenal field or social and physical environment.
    • The inclusion of the subjective field of reality allows for variation among people who would otherwise act or behave similarly.

  • Magnetic Field Lines

    • Magnetic field lines are useful for visually representing the strength and direction of the magnetic field.
    • The magnetic field is traditionally called the B-field.
    • The direction of the magnetic field is tangent to the field line at any point in space.
    • Magnetic field lines can never cross, meaning that the field is unique at any point in space.
    • Relate the strength of the magnetic field with the density of the magnetic field lines

  • Mediterranean Trade and European Expansion

    • The silk and spice trade, involving spices, incense, herbs, drugs, and opium, made these Mediterranean city-states phenomenally rich.

  • Paramagnetism and Diamagnetism

    • Paramagnetism is the attraction of material while in a magnetic field, and diamagnetism is the repulsion of magnetic fields.
    • The magnetic moment induced by the applied field is linear in the field strength; it is also rather weak.
    • When a magnetic field is applied, the dipoles will tend to align with the applied field, resulting in a net magnetic moment in the direction of the applied field.
    • Diamagnetism is the property of an object or material that causes it to create a magnetic field in opposition to an externally applied magnetic field.
    • The eddy currents then produce an induced magnetic field opposite the applied field, resisting the conductor's motion.

  • Neural Underpinnings of Consciousness

    • Scientists believe it may be the case that every phenomenal, subjective state has its own neural correlate.
    • Consciousness can also be phenomenal, such as our experiences in real time, or access, such as recalling a state of being or feeling.

  • Electric Field Lines: Multiple Charges

    • Electric fields created by multiple charges interact as do any other type of vector field; their forces can be summed.
    • Each will have its own electric field, and the two fields will interact.
    • The strength of the electric field depends proportionally upon the separation of the field lines.
    • More field lines per unit area perpendicular to the lines means a stronger field.
    • It should also be noted that at any point, the direction of the electric field will be tangent to the field line.

  • Uniform Electric Field

    • An electric field that is uniform is one that reaches the unattainable consistency of being constant throughout.
    • A uniform field is that in which the electric field is constant throughout.
    • Equations involving non-uniform electric fields require use of differential calculus.
    • In uniform fields it is also simple to relate ∆V to field strength and distance (d) between points A and B:
    • In this image, Work (W), field strength (E), and potential difference (∆V) are defined for points A and B within the constructs of a uniform potential field between the positive and negative plates.

  • Helical Motion

    • What if the velocity is not perpendicular to the magnetic field?
    • The component of the velocity parallel to the field is unaffected, since the magnetic force is zero for motion parallel to the field.
    • shows how electrons not moving perpendicular to magnetic field lines follow the field lines.
    • If field strength increases in the direction of motion, the field will exert a force to slow the charges (and even reverse their direction), forming a kind of magnetic mirror.
    • When a charged particle moves along a magnetic field line into a region where the field becomes stronger, the particle experiences a force that reduces the component of velocity parallel to the field.

  • Electric vs. Magnetic Forces

    • A consequence of this is that the electric field may do work and a charge in a pure electric field will follow the tangent of an electric field line.
    • where B is the magnetic field vector, v is the velocity of the particle and θ is the angle between the magnetic field and the particle velocity.
    • The angle dependence of the magnetic field also causes charged particles to move perpendicular to the magnetic field lines in a circular or helical fashion, while a particle in an electric field will move in a straight line along an electric field line.
    • The electric field is directed tangent to the field lines.
    • Magnetic fields exert forces on moving charges.