User:Darrenvc

Fair-weather cumulus humilus clouds over the Wasatch Mountains of Utah.

Who I Am

I'm a senior in the meteorology department at the University of Utah. I plan to graduate in May of this year, and proceed to a graduate program in atmospheric science in the fall.

Why I Have a Wikipedia Account

As part of a meteorology course I am currently enrolled in, I am required to contribute to the Meteorology WikiProject, and am very much looking forward to this opportunity.

Homework Assignment Part I

This section is temporary

A Wikipedia Featured Article is an article which Wikipedia editors select as an outstanding piece in terms of accuracy, neutrality, style, and completeness. According to the Wikipedia featured article criteria page, a featured article must be "well written, comprehensive, factually accurate, neutral and stable." Furthermore, the article must be structured according to the Wikipedia manual of style. Lastly, its images must not violate copyright laws. Any user can submit an article; the article will then be heavily critiqued by Wikipedia users until a moderator decides that a consensus for nomination has been reached. Featured Articles can be recognized by a bronze-colored star at the top right-hand corner of the page (in line with the article title).

Here is an example of a Wikipedia Featured Article: Enigma Machine

Homework Assignment Part II

This section is temporary

I would like to expand the Wikipedia stub on air parcels with the buoyancy equation and related topics. As of yet, I cannot find where this is referenced in another article. Most of the information would come from textbooks I already have. A few concepts could be pulled from http://meted.ucar.edu/mesoprim/cape/print.htm and other sites that I come across. Another idea is to author an article on the simplified version of the Froude number as it applies to meteorology (as found in http://meted.ucar.edu/mesoprim/flowtopo/print.htm).

Test Section

This section is temporary, I'm testing how the article will appear

Definition

An air parcel is an imaginary volume of air used by meteorologists for conceptualizing the thermodynamic fluid motions of the atmosphere. For mathematical simplicity, an air parcel is usually considered a rigid cube which has limited interactions with surrounding environmental air. The dimensions of this parcel are determined by the atmospheric scale under study.

The importance of the concept air parcels in meteorology lies in its ability to assist meteorologists in conceptualizing how areas of an atmosphere will feature rising and sinking motions, the magnitude of those motions, and the possibility of ensuing clouds and precipitation.

Buoyancy Equations

The weight of the parcel is $\mathrm {V} \mathbf {g}$ , while the pressure gradient force is ${\frac {dp}{dz}}$ . Using the hydrostatic assumption (both terms equal zero) and observing that $\rho V{\frac {dw}{dt}}=0$ in this case gives $\rho V{\frac {dw}{dt}}=-V{\frac {dp}{dz}}-V\rho g$ Allowing for the pressure to be the sum of the environmental and parcel pressure $p={\bar {p}}+p^{\prime }$ yields the following as the buoyancy equation: ${\frac {dw}{dt}}=-{\frac {1}{\rho }}{\frac {dp^{\prime }}{dz}}+{\frac {{\bar {\rho }}-\rho }{\rho }}$ (where ${\frac {dw}{dt}}$ is the bouyancy).

The first term details the effects of pressure perturbation, wherein the parcel must literally "push" surrounding air out of the way to move through the environment.

From the second term it is easily seen that if the parcel is denser than its environment (i.e. $p>{\bar {p}}$ , it will have a negative buoyancy and will thus sink relative to the environment. The opposite case is also true ( $p<{\bar {p}}$ causes rising), while neutral buoyancy is achieved by the two terms being equal. Alternatively, the density can be replaced by the virtual temperature (virtual temperature is necessary because of the density differences between air and water vapor).

In addition to the basic buoyancy equation, there are two other factors which govern parcel movement; precipitation loading and entrainment. If moisture precipitates within the parcel, the amount of precipitation in the parcel versus the amount in the environment will affect the parcel's buoyancy (every drop of precipitation adds extra weight to the parcel). This is described mathematically as a third term in the buoyancy equation ${\bar {w_{c}}}-{w_{c}}$ . Also, if mixing of environmental air with parcel air is considered, the properties of the parcel will change to reflect that of the environment. This process is known as entrainment and is mathematically represented as a coefficient lambda $\lambda ={\frac {1}{\lambda }}{\frac {dm}{d\lambda }}$ (m is the mass of air entrained into the parcel).

Combining all the factors yields an equation which suitably expresses the buoyancy of an air parcel ${\frac {dw}{dt}}=-{\frac {1}{\rho }}{\frac {dp^{\prime }}{dz}}+\lambda ({\frac {{\bar {\rho }}-\rho }{\rho }}+({\bar {w_{c}}}-{w_{c}}))$

This developing thunderstorm can be visualized as a large single air parcel

Applications

When using a Skew-T diagram to diagnose the atmosphere, meteorologists often assume that air interacting with the environment will behave as an air parcel.

The notion of air parcels is partially confirmed by examining convective plumes within cumulous congestus clouds. Individual columns of rising air can be observed in such clouds. In time lapse photography, areas of convection can be observed, and the individual terms of the buoyancy equation can be observed in action.