This question uses slope field reasoning to identify stable equilibrium solutions. For $dy/dx = y^2 - 4 = (y-2)(y+2)$, equilibrium occurs when $dy/dx = 0$, giving $y = 2$ and $y = -2$. For stability, we check the sign of $dy/dx$ near each equilibrium. Near $y = -2$: slightly above gives $(-1.9)^2 - 4 \approx -0.39 < 0$ (decreasing toward $-2$), slightly below gives $(-2.1)^2 - 4 \approx 0.41 > 0$ (increasing toward $-2$). Near $y = 2$: slightly below gives $(1.9)^2 - 4 \approx -0.39 < 0$ (moving away), slightly above gives $(2.1)^2 - 4 \approx 0.41 > 0$ (moving away). Only $y = -2$ attracts nearby solutions, making it stable. Choice B fails because $y = 2$ is unstable as solutions move away from it. To identify stable equilibria in slope fields, find where $dy/dx = 0$ and check if nearby slopes point toward that equilibrium.

This question involves slope field reasoning for equations with bounded derivatives. For $\frac{dy}{dx} = \frac{1}{1+y^2}$, the denominator $1 + y^2$ is always $\geq 1$ for any real $y$, so the slope is always between 0 and 1. Since $1 + y^2 \geq 1$, we have $\frac{1}{1+y^2} \leq 1$, and since $1 + y^2 > 0$, we have $\frac{dy}{dx} > 0$. Therefore, all solution curves have slopes strictly between 0 and 1 everywhere. Choice A fails because solutions are always increasing (positive slope), never decreasing. When analyzing slope fields, examine the range of possible values for $\frac{dy}{dx}$ to understand the constraints on solution behavior and ensure slopes stay within predictable bounds.

This question requires slope field reasoning about slopes along vertical lines. For dy/dx = x/(1+y²) at x = 0, we have dy/dx = 0/(1+y²) = 0 for all y values. Since the numerator is zero when x = 0, the slope equals zero regardless of the y-coordinate, making all slope segments horizontal along the vertical line x = 0. The denominator 1+y² is always positive, so the fraction is well-defined and equals zero. Choice A fails because slopes are zero (horizontal), not infinite (vertical), along x = 0. When analyzing slope fields along vertical lines where the differential equation has x in the numerator, substitute the x-value to see how slopes vary with y.

This question requires slope field reasoning about local solution behavior at specific points. For $\frac{dy}{dx} = \frac{2}{1+x^2} - y^2$ at point (0,2), we evaluate: $\frac{dy}{dx} = \frac{2}{1+0^2} - 2^2 = 2 - 4 = -2 < 0$. A negative slope indicates the solution is locally decreasing at (0,2). The slope magnitude of 2 shows the solution decreases at a moderate rate near this point. Choice A fails because the slope is negative, not positive, indicating decreasing rather than increasing behavior. When analyzing local solution behavior in slope fields, substitute the point's coordinates into the differential equation to determine the slope sign and magnitude at that location.

This question involves slope field reasoning for solutions of equations depending only on x. For dy/dx = e^(-x), the slope depends only on x, not on y, so all solutions are vertical translations of each other. Since e^(-x) > 0 for all x, all solutions are increasing. As x increases, e^(-x) decreases toward 0, so slopes decrease but remain positive, meaning solutions increase at a decreasing rate (concave down). Choice A fails because solutions increase, not decrease, and choice D fails because slopes decrease, not increase. When analyzing slope fields for dy/dx = f(x), remember all solutions have identical slope behavior at each x-value, differing only by vertical shifts.

This problem tests slope field evaluation at specific points. For dy/dx = x/(1+y²), we evaluate the slope at the point (0,2). Substituting x = 0 into the differential equation gives dy/dx = 0/(1+2²) = 0/5 = 0. A slope of 0 means the solution has a horizontal tangent at this point. The answer "vertical tangent" might seem plausible if one confuses the roles of numerator and denominator, but the denominator 1+y² is never zero. When evaluating slopes from differential equations, substitute the exact coordinates and simplify carefully to determine the tangent line's behavior.

This question involves slope field reasoning to predict long-term solution behavior. For dy/dx = x(2-y), when y < 2 and x > 0, we have (positive)(positive) = positive slope, so solutions increase. As these solutions approach y = 2, the factor (2-y) approaches 0, making the slope approach 0, so the solution levels off approaching y = 2. Since y < 2 throughout this process, solutions never actually reach or cross y = 2. Choice A incorrectly suggests solutions move away from y = 2, but positive slopes when y < 2 drive solutions toward this horizontal asymptote. When reading slope fields, identify equilibrium lines where dy/dx = 0 and determine whether solutions approach or diverge from these lines based on nearby slope signs.

This question involves slope field reasoning for bounded slope behavior. For dy/dx = y/(y²+1), we can analyze the range of possible slopes. Taking the derivative of f(y) = y/(y²+1), we get f'(y) = (1-y²)/(y²+1)², which equals 0 when y = ±1. Evaluating f(±1) = ±1/2, and noting f(0) = 0, f(y) → 0 as y → ±∞, the function achieves maximum 1/2 at y = 1 and minimum -1/2 at y = -1. Therefore, slopes are always between -1/2 and 1/2. Choice A fails because slopes can be positive when y > 0. To analyze slope bounds in slope fields, find the range of the differential equation by examining its critical points and limiting behavior.

This question requires using slope field reasoning to analyze solution behavior. For dy/dx = y - x at point (0,1), the slope is 1 - 0 = 1, so the curve is initially increasing. Moving slightly right from (0,1) to small positive x values, the slopes remain positive and even increase since y > x in that region, indicating the curve is concave up. Nearby points show slopes that increase as we move right and up, confirming concave up behavior. Choice A fails because the solution increases rather than decreases initially. To read slope fields effectively, first evaluate the slope at the given point, then examine how slopes change in the immediate neighborhood to determine concavity.

This question requires slope field reasoning for logarithmic differential equations. For dy/dx = ln(1+y) with y > -1, we need to analyze when ln(1+y) is positive, negative, or zero. Since ln(1+y) > 0 when 1+y > 1, i.e., when y > 0, solutions with y > 0 have positive slope and are increasing. When -1 < y < 0, we have 0 < 1+y < 1, so ln(1+y) < 0, making these solutions decreasing. When y = 0, ln(1) = 0, giving a horizontal tangent. Choice C fails because solutions with -1 < y < 0 are decreasing, not increasing. To analyze slope fields involving logarithmic functions, determine where the logarithmic expression is positive, negative, or zero based on its argument.