My apologies for the double-response. I accidentally answered your question as a comment rather than as an answer.
If I am understanding correctly, I think I have found a simple way of doing what you want.
First, let me copy-paste your code without the quiver3 function:
% Define the function
z = @(x, y) x.^2 + y.^2;
% Point of interest
point_x = -1;
point_y = -1;
point_z = z(point_x, point_y);
deltax = 0.5;
deltay = 0.5;
% Calculate the gradient analytically
gradient_x = 2*point_x;
gradient_y = 2*point_y;
gradient_z = 0;
% Plot the surface
[x_vals, y_vals] = meshgrid(linspace(-2, 2, 50), linspace(-2, 2, 50));
z_vals = z(x_vals, y_vals);
surfc(x_vals, y_vals, z_vals,'EdgeColor','none','FaceColor','interp','FaceAlpha',0.7);
hold on;
% Plot the point of interest
scatter3(point_x, point_y, point_z, 30, 'r', 'filled');
% Add labels and title
xlabel('X-axis');
ylabel('Y-axis');
zlabel('Z-axis');
view(-22,6)
I swapped the surf function for surfc which plots a contour map underneath the surface plot. I also got rid of the edge lines and interpolated the colors to make the visalization less busy. You can revert to your original surf plot if you prefer. Moreover, I used the view function to change the azimuth angle to get a different perspective of the axes.
Now, to add the vector arrow, I am going to calculate an infinitesimally small change for each x, y, and z coordinate of your point of interest. The change in slope at this point is what I am going to use to define the vector arrow.
% Infinitesimally small change
infchange = 0.0000000001;
point_xinf = point_x + infchange;
point_yinf = point_y + infchange;
point_zinf = z(point_xinf, point_yinf);
% Calculate the difference relative to the original point
dx = point_xinf - point_x;
dy = point_yinf - point_y;
dz = point_zinf - point_z;
% Add vector arrow to map
quiver3(point_x,point_y,point_z,...
dx*20e8,dy*20e8,dz*20e8,'Color','r',...
'LineWidth',1,...
'ShowArrowHead','on',...
'MaxHeadSize',0.6)
