b. Recycling paper can lead to 74% less air pollution.
c. Paper recycling can save on the use of water resources.
d. Recycling paper can lead to 35% less water pollution.
The statement presented above that is not true about paper recycling is; A) Recycling one ton of newspaper can save 100 trees.
Paper recycling are the processes of reprocessing waste paper such as old newspapers and magazines into new paper products for reuse. Apart from saving trees from being cut, paper recycling has many other significant benefits such as reducing water and air pollution, saving on the use of water resources and energy. For every ton (200 pounds) of newspaper that is recycled, 17 trees are saved.
The false statement here is that; "recycling paper can lead to 35% less water pollution." The idea of recycling a huge environmental conservation effort.
The term recycling has to do with the process of using a material for the same or another purpose rather than simply disposing the material after it has been used. The idea of recycling a huge environmental conservation effort.
The false statement here is that; "recycling paper can lead to 35% less water pollution."
Learn more about recycling- brainly.com/question/11861824?:
Answer:
Explanation:
Several scientists have made significant contributions to our current understanding of genetics. Here are a few examples:
1. Gregor Mendel: Mendel is often referred to as the "father of genetics." In the 19th century, he conducted groundbreaking experiments with pea plants and discovered fundamental principles of inheritance. His work laid the foundation for our understanding of how traits are passed down from one generation to another.
2. James Watson and Francis Crick: In the 20th century, Watson and Crick, along with Maurice Wilkins, elucidated the structure of DNA. Their discovery of the double helix structure in 1953 revolutionized our understanding of how genetic information is stored and transmitted. This laid the groundwork for modern molecular genetics.
3. Rosalind Franklin: Although often overshadowed, Franklin played a critical role in the discovery of DNA's structure. Her X-ray crystallography images provided crucial evidence that helped Watson and Crick develop their model. Franklin's work contributed to our understanding of DNA's physical properties and its role in inheritance.
4. Barbara McClintock: McClintock's research on corn plants in the mid-20th century revealed the existence of "jumping genes" or transposable elements. Her findings challenged the traditional view of genes as fixed entities and highlighted the dynamic nature of genetic material. McClintock's work earned her the Nobel Prize in Physiology or Medicine in 1983.
These scientists, along with many others, have made significant contributions to our understanding of genetics. Their discoveries have paved the way for further advancements in the field, leading to breakthroughs in areas such as genetic engineering, gene therapy, and personalized medicine.
A monohybrid cross involves the study of one trait at a time, while a dihybrid cross involves the study of two traits simultaneously.
A monohybrid cross is a genetic cross that involves the study of one trait at a time. It is focused on analyzing the inheritance of only one pair of alleles. In contrast, a dihybrid cross is a genetic cross that involves the study of two traits simultaneously. It is used to determine the patterns of inheritance for two different gene pairs.
For example, let's consider a monohybrid cross involving flower color in pea plants. If we cross a purebred yellow flowered pea plant (YY) with a purebred green flowered pea plant (yy), the resulting offspring will all have yellow flowers (Yy). In a dihybrid cross, we would consider two traits, such as flower color and seed shape. We could cross a purebred yellow, round-seeded plant (YYRR) with a purebred green, wrinkled-seeded plant (yyrr), resulting in offspring with yellow, round seeds (YyRr).
In summary, the main difference between a monohybrid cross and a dihybrid cross is that a monohybrid cross focuses on one pair of alleles for one trait, while a dihybrid cross focuses on two pairs of alleles for two different traits.
#SPJ12
The equation for the thermal efficiency of a system is given by n = Tc/Thx100 where n is the thermal efficiency, Tc is the temperature of the cold reservoir and Th is the temperature of the hot reservoir. Dividing 190 by 515 gives us an efficiency of 36.9%.
Answer: A.
63.1%
Explanation: edmentum
b. water will move out of the cell causing it to shrivel.