To find the total charge $Q$ on the rectangular surface, we need to integrate the charge density $\sigma(x, y)$ over the surface area:

$$Q = \int_{0}^{b} \int_{0}^{a} \sigma(x, y) dx dy$$

Substituting $\sigma(x,y)=kxy$ into the above expression and performing the integrals yields:

\begin{align*} Q &= \int_{0}^{b} \int_{0}^{a} k x y dx dy \ &= k \int_{0}^{b} \left[\frac{x^2}{2} y \right]{x=0}^{x=a} dy \ &= k \int{0}^{b} \frac{a^2}{2} y dy \ &= \frac{k a^2}{2} \left[\frac{y^2}{2} \right]_{y=0}^{y=b} \ &= \frac{k a^2 b^2}{4} \end{align*}

Therefore, the total charge on the rectangular surface is $\boxed{\frac{k a^2 b^2}{4}}$.

To find the total charge on the circular plate of radius $R$ with charge distribution $\sigma(r,\theta) = kr(1-\sin\theta)$, we need to integrate the charge density over the entire area of the plate.

The charge density $\sigma$ is a function of $r$ and $\theta$, where $r$ is the radial distance from the center of the plate and $\theta$ is the angle measured from some reference direction. Since the plate is circular, we can integrate over $r$ and $\theta$ as follows:

\begin{align*} Q &= \int_{0}^{2\pi}\int_{0}^{R} \sigma(r,\theta)r,dr,d\theta \ &= \int_{0}^{2\pi}\int_{0}^{R} k r^2 (1-\sin\theta),dr,d\theta\ &= k \int_{0}^{2\pi}\left[\frac{r^3}{3} – r^2\cos\theta\right]{r=0}^{r=R},d\theta\ &= k \int{0}^{2\pi}\left(\frac{R^3}{3} – R^2\cos\theta\right),d\theta\ &= k\left[\frac{R^3}{3}\theta – R^2\sin\theta\right]_{\theta=0}^{\theta=2\pi}\ &= k\left(\frac{2}{3}\pi R^3 – 0\right)\ &= \frac{2}{3}\pi k R^3 \end{align*}

Therefore, the total charge on the circular plate is $\frac{2}{3}\pi k R^3$.

To apply Gauss’s Law, we need to choose a closed surface that encloses the region of interest, which in this case is the region between the inner and outer cylinders. A convenient choice is a cylindrical Gaussian surface of radius $r$ and height $l$, centered on the axis of the cylinders. The electric field will be perpendicular to the surface at every point, so the flux of the electric field through the surface is simply the product of the magnitude of the field and the area of the curved surface:

$$\Phi_E = \oint_S \vec{E} \cdot d\vec{A} = E(r) 2\pi rl$$

where $E(r)$ is the magnitude of the electric field at radius $r$ and $d\vec{A}$ is a differential area element of the surface.

By Gauss’s Law, the flux through the surface is equal to the enclosed charge divided by the permittivity of free space:

$$\Phi_E = \frac{Q_{enc}}{\epsilon_0}$$

where $Q_{enc}$ is the charge enclosed by the Gaussian surface. Since the inner cylinder is the only source of charge inside the surface, the enclosed charge is simply $Q_{enc}=Q$.

Setting these two equations equal to each other, we have

$$E(r) 2\pi rl = \frac{Q}{\epsilon_0}$$

Solving for $E(r)$, we obtain:

$$E(r) = \frac{Q}{2\pi\epsilon_0 rl}$$

The direction of the electric field is radial, i.e., pointing outward from the axis of the cylinders if $Q$ is positive and inward if $Q$ is negative.

Therefore, the magnitude of the electric field between the cylinders is given by:

$$\boxed{E(r) = \frac{Q}{2\pi\epsilon_0 rl}}$$