with your help I've come pretty far with this problem in the past two weeks so thank you so much to this wonderful community!!

First off I want to make the following clear: I don't expect a solution, but I would like some help finding modules (in any programming language) that could help me get closer to my desired solution. Also if you have any mathematical advice on achieving my solution I will happily accept it! I'm currently using MATLAB but if there is a programming language that is better catered to getting my desired result I'll happily give it a shot!

My problem is as follows:

In short, I want to find the amount of Nitrogen dioxide along a path from the ground to the "top of the atmosphere" given a field of model data that I have.

My issue is that for each combination of altitude level (assigned as 1->27), latitude (assigned as a point 1 -> 364) and longitude (assigned as a point 1-> 264) there is a set amount of nitrogen dioxide present at that position. This means that the grid boxes are not infinitely small so I'm having trouble visualizing and coming up with how I would find the amount of nitrogen dioxide along a line through space.

Here are some visualizations:

First is a 2D grid representation. As you can see, each grid box has a "set amount" of NO2 within it for each combination of position and altitude. Currently my code has the capacity to solve for, for instance, the total amount of NO2 within column B. Basically, I can solve for NO2 along a vertical straight line! 2D Grid Here is the second reprsentation, and the same constant amount for each grid box holds true here as well. The main difference is that this is in the 3 dimensions and is more representative of the product I'm aiming at. Basically I want the amount of a thing between point one and point 2.

3D Grid

Currently I've managed to, at a combination of latitude and longitude (ignore the fourth dimension, its just time. That is a dimension I'll get to with a later addition to this project), sum for the total amount of nitrogen dioxide within the atmosphere (also known as a vertical column) with following code:

av = 6.022140857747*(10^23); % Avogadro's Number 1/mol
R = 82.06; % Gas Constant cm3*atm/(k*mol)

Pres_atm = Pres*(1/101325); % Changes the pressure matrix to units of atm
no2_moleccm3 = no2*(1/(10^6))*av.*Pres_atm*(1/R).*(1/Temp); % Conversion of no2 
to molecules/cm3

% For loop that changes the total height to a difference of heights for
% each altitude layer of 2->27
for index = 2:27
    h(:,:,index,:) = flheight(:,:,index,:) - flheight(:,:,index-1,:);

h(:,:,1,:) = flheight(:,:,1,:); % Adding the first altitude layer

% For loop that changes the total mid-layer height to a height difference
% at each altitude 2->27
for index = 2:27
    mh(:,:,index,:) = mlheight(:,:,index,:) - mlheight(:,:,index-1,:);

mh(:,:,1,:) = mlheight(:,:,1,:); % Adding the first mid altitude layer 

no2_moleccm2 = no2_moleccm3.*h(:,:,:,:); % Converts no2 to units of molecules 
per unit area.

vcol = sum(no2_moleccm2(1,1,:,12)) % Calculates a vertical column for any 
combination of time, lat, and lon.

I'm getting a pretty decent answer for the vertical column amount, pretty much exactly what I desire.

Now, I want to build some code that can find a similar quantity, but tracking (per my code) the "no2_moleccm2" over a slant column instead of a vertical column. So basically instead of going from "the ground" to a point "at the top of the atmosphere directly above it" I want to go from the ground to the top of the atmosphere at another combination of latitude and longitude.

Again, I don't expect a solution but I would really appreciate any advice on this problem!

Best, Taylor

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