New York's iconic, blue-green statue of liberty wasn't always green. When the statue was gifted to the US from France in 1885, she was actually a shiny copper color. A new video reveals the chemical reactions involving oxygen and even air pollution that led to her color change from copper to liberty green. The statue of liberty was a gift from France to the US as a way of commemorating the US's fight for independence, as well as their own aspiration for democracy.

    A video, published by the American Chemical Society, explains that the 305-foot (93 meter) statue was built over nine years in sections of copper skin on top of an iron skeleton.

    In her first few decades in the Big Apple, the statue slowly turned from that shiny copper color to a dull brown and the, finally, to the blue-green, or as they'd say back in France, 'verdigris' we see today,' said the video's narrator.

When it changed color, some officials suggested restoring her back to her original color, but after the public protested against this decision, she was left the way she is. The statue's color change was as a result of oxidation reactions between copper and the air. But it was more than one reaction - the color change is due to about 30 years worth of different reactions leading to a mixture of greenish minerals.

    Oxidation reactions happen when an atom loses an electron to another atom.

    In the case of the statue of liberty, her color change was bound to happen due to oxygen in the atmosphere that is 'hungry' for electrons. On top of this, elements of New York City's polluted air added to the color change too.

The first chemical reaction of the color change involved copper giving up electrons to electron-hungry oxygen in the atmosphere. This led to a mineral called cuprite - which is pinkish red.

    Then, cuprite loses even more electrons to oxygen, forming a new mineral（矿物质） called tenorite, which is blackish in color. The black color of tenorite explains why the statue got darker over time, forming a dark brown color.

    Then, further chemical reactions occurred when sulfur（硫） in the atmosphere reacts with oxygen to form sulfur dioxide. Sulfur comes from natural processes such as volcanic eruptions, but also from man-made emissions from boats, cars, airplanes and factories. When sulfur dioxide in the atmosphere reacts with water, it produces sulfuric acid. Sulfuric acid forms green minerals with copper oxides, so the sulfuric acid in the atmosphere made the state green over time.

    Added to that, chloride from the sea spray surrounding Ellis Island where the statue is located made the statue even greener.

    The statue stayed this way for over 100 years because the exposed copper is now oxidized and stable, but the statue wouldn't be the same anywhere else.

材料：在一阴湿山洼丛中，有一堆长满葫芦藓的腐木，其中聚集着蚂蚁、蜘蛛、老鼠等动物．请根据材料，从生命系统的结构层次上试分析各自对应于哪个层次．

注： $\sqrt{n}$ 中的n表示作物所种的公顷数。

现有一个较大的生态系统，其中包括1000公顷（1公顷=10000米²）的农田、一个1.0×10⁵米²的湖泊以及一种必须加以保护的食鱼鹰等。又有2种可供选择种植的经济作用（作物1和作物2），一年只能种植一季，有关这2种作物种植所涉及的一些参数见上表。由表可知，不同作物的经费投入、收入、施药量及流失率不同。

湖水最初未受污染，种植作物后，会因农药的流失，有一定量的农药由流经农田的水流带入湖泊（假定流入湖泊中的农药不会流失），而湖泊中水的体积常年稳定在2.0×10⁵米³。湖水中的农药会沿着食物链：浮游藻类→食藻鱼类→食鱼鹰，在生物体内逐步积累，越到食物链的后端，体内农药的质量分数越大。假定该种食鱼鹰体内最大可承受的农药质量分数为2.69×10^-4，由此换算出湖水中农药的质量分数最大不能超过4.05×10^-6。

（注：①因源水质量巨大，在计算过程中可将湖水质量视作溶液质量；② $\sqrt{1000}\approx$ 32）请你运用所学的知识回答下列问题：