Define x = e^{-0.01t}, so that the problem becomes 50 x^2 = (75 x + 10)/2 whose solutions are x = \frac{15 \pm \sqrt{385}}{40} Takes only the positive, because x>0, and then you get e^{-0.01t} = x= 0.865535 \quad\Rightarrow\quad t = 14.4407

You have the formula m = m_0e^{-0.02t} and are given the original mass, m_0, of 500g and want to find the mass, m, after t=10 years. All you have to do is plug in these values m = m_0e^{-0.02t} = 500e^{-0.02 \cdot 10} ...

Since X(t) is a Poisson process and T is independent of \{X(t):t\geq 0\}, it follows that \mathbb{P}(X(T)=n|T=t)=\mathbb{P}(X(t)=n)=\frac{(\lambda t)^ne^{-\lambda t}}{n!} for n=0,1,2,\dots ...

Basically the value keeps decreasing by 2%, that is, the value of the yen after one year is 98% of the value it was in the previous year. Translating this mathematically, we can get \text{Value of Yen after one year} = Y_1 = 240\times \frac{98}{100} ...

For i=20e{^{-5000t}}, I could say\int_{0}^{t}20e{^{-5000t}}(q)\, dq\, \; =\; q(t), t\,20e{^{-5000t}}=q(t) No, you have to respect the rules for integrals: q(t)=\int_{0}^{t}20e{^{-5000t'/\text{s}}}\text{A}\, dt'\, \; =\; \left[\frac{20\text{s}}{-5000}\cdot e{^{-5000t'}}\right]^t_0 \; {= \; \left[-0.004\cdot e{^{-5000t'}}\text{A}\text{s}\right]^t_0 }{= 0.004\cdot(1-e{^{-5000t}})\ \text{A}\text{s},} ...

Your solution is wrong. True is \frac{d}{dt}(e^{-αt}P(t))=e^{-αt}(\dot P(t)-αP(t)) = 0 so that e^{-αt}P(t)=const.=P(0) so that \dot P=αP has the only solution P(t)=e^{αt}P(0). You ...