Thursday, May 31, 2007
A Family Reunion That Pays
Texas Hill Country is the perfect place for a family reunion. And it helps a lot to have a niece there to make all the arrangements, secure the perfect spot on the shore of Lake Travis, have her boat on hand for exciting rides, provide food and games and even T-shirts with the Gunn Clan logo and family tree. I suppose she even ordered the drought-breaking rains that refilled the lake and kept the sky overcast, temperature mild. Thanks, Nancy and Barbara, for all the hard work!
Peg's granddaughter, Amanda, served ably as our chauffeur, keeping stress levels to a minimum as we hustled from airport to motel to lakeside. When they dropped me off at the airport Sunday morning, I had just found the proper gate when the gal at the desk asked for volunteers to take a later flight for a $50 bonus. I told her I would just as soon go to Lubbock to meet my new great-granddaughter, and my total refund came to $73. While waiting the extra hour for my flight to Lubbock via Dallas, who should turn up but Nancy and Barbara on their way to Alabama to watch the Angelo State baseball team (coached by Nancy's brother-in-law, Kevin Brooks) play in the College World Series. We enjoyed a nice visit until flight time.
In Lubbock I was treated like a queen, as usual, and 4-week-old Kiah Trent was the icing on the cake. The whole family got together for two meals before I headed back to ABQ, again via Dallas. Upon arrival at Love Field, there came another request for volunteers, this time $100 to wait five minutes for the next flight. We barely had time to get the paperwork done before loading. This flight, after unloading a few passengers at the Sunport in ABQ, was headed for San Diego. I thought about just going on out to visit with Peggy's family and see if I could get any more good deals at the airport. But basketball practice was calling. It's good to be home.
Cora Gail Trent
www.cgtrent.com
cgtrent@att.net
Peg's granddaughter, Amanda, served ably as our chauffeur, keeping stress levels to a minimum as we hustled from airport to motel to lakeside. When they dropped me off at the airport Sunday morning, I had just found the proper gate when the gal at the desk asked for volunteers to take a later flight for a $50 bonus. I told her I would just as soon go to Lubbock to meet my new great-granddaughter, and my total refund came to $73. While waiting the extra hour for my flight to Lubbock via Dallas, who should turn up but Nancy and Barbara on their way to Alabama to watch the Angelo State baseball team (coached by Nancy's brother-in-law, Kevin Brooks) play in the College World Series. We enjoyed a nice visit until flight time.
In Lubbock I was treated like a queen, as usual, and 4-week-old Kiah Trent was the icing on the cake. The whole family got together for two meals before I headed back to ABQ, again via Dallas. Upon arrival at Love Field, there came another request for volunteers, this time $100 to wait five minutes for the next flight. We barely had time to get the paperwork done before loading. This flight, after unloading a few passengers at the Sunport in ABQ, was headed for San Diego. I thought about just going on out to visit with Peggy's family and see if I could get any more good deals at the airport. But basketball practice was calling. It's good to be home.
Cora Gail Trent
www.cgtrent.com
cgtrent@att.net
Sunday, May 20, 2007
Too Old to Learn New Tricks?
Who would have believed how much fun old ladies can have playing basketball? The exercise is super, building stamina like a 17-year-old. Well, almost! There is much to learn, new challenges every practice session, and everyone is so helpful.
Playing only half court sounds easy, right? Wrong! Movement is constant, no rest for the weary. Everybody plays both offense and defense, which takes some getting used to. One of the different rules is that during a free throw, everyone but the shooter stands behind the free throw circle. After she shoots, she retrieves the ball and throws it to a team mate outside the circle, then playing resumes as usual.
There is a state tourney next weekend and nationals in November every two years, always held in a different city. Adventure awaits.
Cora Gail Trent
www.cgtrent.com
cgtrent@att.net
Playing only half court sounds easy, right? Wrong! Movement is constant, no rest for the weary. Everybody plays both offense and defense, which takes some getting used to. One of the different rules is that during a free throw, everyone but the shooter stands behind the free throw circle. After she shoots, she retrieves the ball and throws it to a team mate outside the circle, then playing resumes as usual.
There is a state tourney next weekend and nationals in November every two years, always held in a different city. Adventure awaits.
Cora Gail Trent
www.cgtrent.com
cgtrent@att.net
Wednesday, May 09, 2007
Old Age Adventure
Ya know when you go back to visit the old home place and the house seems smaller than when you were a kid? Well, the opposite seems to be true with a basketball court. Last night I joined up with the Canyon Nets for practice, and found a 3-pointer is nigh impossible, a free throw iffy. The goal may even be higher. ;-) But the fun is the same as 53 years ago when I last played in a game. These ladies are a super group, spread the welcome mat wide for this stranger, so I felt right at home. Drills twice a week should have me back in shape in nothing flat. I'm even thinking about learning to throw a shot put, javelin and discus, something that was not offered to girls when I was in school. There seems to be no end to old age adventure.
Cora Gail Trent
www.cgtrent.com
cgtrent@att.net
Cora Gail Trent
www.cgtrent.com
cgtrent@att.net
Tuesday, May 08, 2007
Basketball--Then and Now
When I first fell in love with basketball, girls were not allowed to dribble like the boys--only one bounce. Then it was extended to two, and eventually as many as necessary. We played on half the court, as it was supposed that girls didn't have the stamina for full court. No matter the distance of a shot, any field goal counted two points. How times have changed!
Mama would sometimes join us on our dirt court at home. Having graduated in 1916, her rules were much different. Her shots were pitched underhand, and when she got ready to pitch, her guard was required to stand back and give her free access to the goal. Their uniform consisted of long stockings, bloomers and middy blouses.
In the days before schools were classed by size, the Carey (Texas) Cardinals basketball team played against all sizes of schools and won the state championship. Scores then seldom hit the 20 mark. Carey had no football team, played basketball from fall until baseball season. To us, in the 40s and 50s, they were like professionals, the cream of the crop, and always won the Flomot tournament. Then the UIL restricted their extended season and spoiled the fun.
Tonight I'll be joining a group of senior women to play half-court basketball, picking up where I left off over 50 years ago. Be watching for me in the Senior Olympics!
Cora Gail Trent
www.cgtrent.com
cgtrent@att.net
Mama would sometimes join us on our dirt court at home. Having graduated in 1916, her rules were much different. Her shots were pitched underhand, and when she got ready to pitch, her guard was required to stand back and give her free access to the goal. Their uniform consisted of long stockings, bloomers and middy blouses.
In the days before schools were classed by size, the Carey (Texas) Cardinals basketball team played against all sizes of schools and won the state championship. Scores then seldom hit the 20 mark. Carey had no football team, played basketball from fall until baseball season. To us, in the 40s and 50s, they were like professionals, the cream of the crop, and always won the Flomot tournament. Then the UIL restricted their extended season and spoiled the fun.
Tonight I'll be joining a group of senior women to play half-court basketball, picking up where I left off over 50 years ago. Be watching for me in the Senior Olympics!
Cora Gail Trent
www.cgtrent.com
cgtrent@att.net
Wednesday, May 02, 2007
God's Design
The following article is taken from John Clayton’s Dandy Designs, a collection of articles from the bi-monthly bulletin, Does God Exist?, July, 1979. I think you will find it fascinating.
One of the evidences for the existence of God that we have repeatedly presented in this publication is the evidence from science that there is design in the creation. If one can prove there is design in the creation, one knows there has to be a Designer because design cannot occur in living or in non-living things by chance. We believe this Designer is God and that if an intelligent, thinking person will examine the evidence available, they will see it is impossible for these things to occur by any other process than God’s intelligence and direction. The Bible repeatedly makes reference to these things, telling us in Romans 1:19-23, for example, that we can know there is a God through the things He has made. We are all familiar with passages such as the one in Psalms which tell us the heavens declare the glory of God and the firmament showeth His handiwork. There are numerous claims throughout the Bible maintaining that God’s design is able to be seen in His creation.
One of the more beautiful examples of design in living things is in the structure of the bird egg. You may think in looking at an egg that it is really not that remarkable a structure, but repeated studies done by scientists in various areas and with various features of experimental design have shown that, in fact, the egg is a really incredible structure. Readers may wish to investigate Scientific American (February, 1979 or March, 1970) to see more material along this line. The article in Scientific American in March of 1970 on how an egg shell is made is particularly interesting.
The interesting thing about a bird egg is that it is a self-contained life support system. All the nutrients, minerals, energy sources, and water that will be needed by the embryo during its incubation are already present in a freshly laid egg. But there is one thing that the egg does not have and this is oxygen. Somehow, the egg has to be able to provide oxygen to the organism inside and yet get rid of the waste products that are involved. How do you do this through an apparently impenetrable egg shell? We have to realize that the eggs of birds and other organisms such as spiders and reptiles do not show any respiratory movements. There are no air currents within the egg, and there are no capillaries involved. Instead, the egg must breathe by a process chemically known as diffusion.
Diffusion is the process by which gases move from areas of high concentration to low concentration. In the area of an egg shell, diffusion is through thousands of microscopic pores in the shell of the egg. The lower concentrations of oxygen inside the egg allow oxygen to diffuse through the shell from outside. The high concentration of carbon dioxide inside the egg shell allows the gases to move out to spread into the atmosphere outside where the carbon dioxide is of a lower concentration. One has to realize there is virtually no carbon dioxide in our atmosphere, but about 21% oxygen. Apparently, God has not only designed the bird egg to be able to make these exchanges, but has designed the atmosphere with the capability of exchanging as well.
An interesting experiment which has been done along these lines is to attach an egg to a source of air and put it under water. By injecting pressurized air into the egg shell at the blunt end of a chicken egg, bubbles are seen to emerge from the entire surface of the shell. This experiment was first done by John Davy of Edinburg in 1863, but has been recently reproduced and circulated in numerous photographs by Dennis Atkinson of State University of New York at Buffalo. We have actually discovered that the chicken egg has about 10,000 microscopic pores distributed all over its surface which exchange the gases with its atmosphere.
It is also interesting to notice that the water content of the air within the egg is greater than the water content of the air outside the egg. This means that the pores not only allow oxygen to diffuse through the pores, but also allow water molecules to diffuse out. Bird eggs are designed to lose water at a controlled rate. Most of the energy needed for embryonic development is taken from the fat material stored inside the yolk. For every gram of fat burned, there is also equal mass of water generated. This means that the relative water content of the egg during incubation will decrease. If the relative water content at hatching were to be measured and compared to the water content when the egg was laid, it would be found that about 15% of the original mass of the egg was lost. Those who raise chickens are aware that the longer an egg sits, the more water loss there is. This is the amount of water loss that is essential for successful hatching, and scientists have even learned to determine whether an egg is progressing satisfactorily or not by whether or not it is losing the right amount of water.
During the 21 days that it takes a chicken egg to hatch, an egg which weighs about 60 grams will take up about 6 liters of oxygen, give off 4½ liters of carbon dioxide and 11 liters of water vapor.
The shell of a chicken egg is made of a material similar to limestone. The material is calcium carbonate which forms columnar calcite crystal. These crystals are imperfect, having a small amount of organic material within them. The imperfect packing of these crystals leaves spaces that allow the material to be transported through the egg. The permeability or conductance of the shell to gases is delicately controlled to meet the embryonic needs inside the egg. If gas is conducted too rapidly through the shell, the egg will dehydrate and if gas conductance is too low, the baby chick inside will suffocate.
A happy medium must be struck between the rates at which the gases are conducted through the shell. The way this is done is that as metabolism takes place and gas enters the shell to replace the lost water, an air cell is formed at the blunt end of the egg. The air cell grows until it occupies about 15% of the internal volume of the egg. This occurs at the end of the incubation period. The oxygen consumption of the embryo increases slowly during the first week and a half of life; between 10-14 days it reaches a plateau which it maintains up until hatching. This plateau of 6 milliliters of oxygen per day is the volume that the pores of the cell are able to pass by diffusion. This means that the rate of oxygen movement is exactly equal to what the shell is able to diffuse. In different terms, what this means is that every second about 20 trillion oxygen atoms flow into the egg through each cell and 14 trillion molecules of carbon dioxide and 12 trillion molecules of water vapor flow out.
All of this intricately designed system provides for the chick up until about the 19th day. On or about the 19th day, the chick penetrates the air cell at the blunt end of the egg with its beak. This process is called “internal pipping.” The chick then begins to breathe from this air cell ventilating its previously unused lungs. During this period, oxygen is provided by both diffusion and convection. About six hours after the chick has penetrated the air cell in the eggs, it pokes a hole in the shell. This small hole produced by the egg tooth on the upper beak of the chick provides atmospheric oxygen for the first time. By this time the lung function is well enough established to allow increased oxygen consumption which is required during the final effort of hatching.
The engineering principles involved in this process are even more remarkable when one considers different kinds of eggs. Not all eggs have the same size pores, but all eggs end up producing the same final concentrations of oxygen and carbon dioxide within the egg. It is rather remarkable when one considers that the incubation of bird eggs ranges all the way from 11 days in some small birds to 70 days for large birds such as the Wandering Albatross. The chemistry involved in a system such as this of moving gases and providing for the embryo inside the egg seems virtually impossible to explain in terms of any kind of evolutionary process. It is another example of God’s wisdom and design in the creation–a design that demands a Designer.
Cora Gail Trent
www.cgtrent.com
cgtrent@att.net
* * *
THE BIRD EGG
AN EXAMPLE OF GOD’S DESIGN
THE BIRD EGG
AN EXAMPLE OF GOD’S DESIGN
One of the evidences for the existence of God that we have repeatedly presented in this publication is the evidence from science that there is design in the creation. If one can prove there is design in the creation, one knows there has to be a Designer because design cannot occur in living or in non-living things by chance. We believe this Designer is God and that if an intelligent, thinking person will examine the evidence available, they will see it is impossible for these things to occur by any other process than God’s intelligence and direction. The Bible repeatedly makes reference to these things, telling us in Romans 1:19-23, for example, that we can know there is a God through the things He has made. We are all familiar with passages such as the one in Psalms which tell us the heavens declare the glory of God and the firmament showeth His handiwork. There are numerous claims throughout the Bible maintaining that God’s design is able to be seen in His creation.
One of the more beautiful examples of design in living things is in the structure of the bird egg. You may think in looking at an egg that it is really not that remarkable a structure, but repeated studies done by scientists in various areas and with various features of experimental design have shown that, in fact, the egg is a really incredible structure. Readers may wish to investigate Scientific American (February, 1979 or March, 1970) to see more material along this line. The article in Scientific American in March of 1970 on how an egg shell is made is particularly interesting.
The interesting thing about a bird egg is that it is a self-contained life support system. All the nutrients, minerals, energy sources, and water that will be needed by the embryo during its incubation are already present in a freshly laid egg. But there is one thing that the egg does not have and this is oxygen. Somehow, the egg has to be able to provide oxygen to the organism inside and yet get rid of the waste products that are involved. How do you do this through an apparently impenetrable egg shell? We have to realize that the eggs of birds and other organisms such as spiders and reptiles do not show any respiratory movements. There are no air currents within the egg, and there are no capillaries involved. Instead, the egg must breathe by a process chemically known as diffusion.
Diffusion is the process by which gases move from areas of high concentration to low concentration. In the area of an egg shell, diffusion is through thousands of microscopic pores in the shell of the egg. The lower concentrations of oxygen inside the egg allow oxygen to diffuse through the shell from outside. The high concentration of carbon dioxide inside the egg shell allows the gases to move out to spread into the atmosphere outside where the carbon dioxide is of a lower concentration. One has to realize there is virtually no carbon dioxide in our atmosphere, but about 21% oxygen. Apparently, God has not only designed the bird egg to be able to make these exchanges, but has designed the atmosphere with the capability of exchanging as well.
An interesting experiment which has been done along these lines is to attach an egg to a source of air and put it under water. By injecting pressurized air into the egg shell at the blunt end of a chicken egg, bubbles are seen to emerge from the entire surface of the shell. This experiment was first done by John Davy of Edinburg in 1863, but has been recently reproduced and circulated in numerous photographs by Dennis Atkinson of State University of New York at Buffalo. We have actually discovered that the chicken egg has about 10,000 microscopic pores distributed all over its surface which exchange the gases with its atmosphere.
It is also interesting to notice that the water content of the air within the egg is greater than the water content of the air outside the egg. This means that the pores not only allow oxygen to diffuse through the pores, but also allow water molecules to diffuse out. Bird eggs are designed to lose water at a controlled rate. Most of the energy needed for embryonic development is taken from the fat material stored inside the yolk. For every gram of fat burned, there is also equal mass of water generated. This means that the relative water content of the egg during incubation will decrease. If the relative water content at hatching were to be measured and compared to the water content when the egg was laid, it would be found that about 15% of the original mass of the egg was lost. Those who raise chickens are aware that the longer an egg sits, the more water loss there is. This is the amount of water loss that is essential for successful hatching, and scientists have even learned to determine whether an egg is progressing satisfactorily or not by whether or not it is losing the right amount of water.
During the 21 days that it takes a chicken egg to hatch, an egg which weighs about 60 grams will take up about 6 liters of oxygen, give off 4½ liters of carbon dioxide and 11 liters of water vapor.
The shell of a chicken egg is made of a material similar to limestone. The material is calcium carbonate which forms columnar calcite crystal. These crystals are imperfect, having a small amount of organic material within them. The imperfect packing of these crystals leaves spaces that allow the material to be transported through the egg. The permeability or conductance of the shell to gases is delicately controlled to meet the embryonic needs inside the egg. If gas is conducted too rapidly through the shell, the egg will dehydrate and if gas conductance is too low, the baby chick inside will suffocate.
A happy medium must be struck between the rates at which the gases are conducted through the shell. The way this is done is that as metabolism takes place and gas enters the shell to replace the lost water, an air cell is formed at the blunt end of the egg. The air cell grows until it occupies about 15% of the internal volume of the egg. This occurs at the end of the incubation period. The oxygen consumption of the embryo increases slowly during the first week and a half of life; between 10-14 days it reaches a plateau which it maintains up until hatching. This plateau of 6 milliliters of oxygen per day is the volume that the pores of the cell are able to pass by diffusion. This means that the rate of oxygen movement is exactly equal to what the shell is able to diffuse. In different terms, what this means is that every second about 20 trillion oxygen atoms flow into the egg through each cell and 14 trillion molecules of carbon dioxide and 12 trillion molecules of water vapor flow out.
All of this intricately designed system provides for the chick up until about the 19th day. On or about the 19th day, the chick penetrates the air cell at the blunt end of the egg with its beak. This process is called “internal pipping.” The chick then begins to breathe from this air cell ventilating its previously unused lungs. During this period, oxygen is provided by both diffusion and convection. About six hours after the chick has penetrated the air cell in the eggs, it pokes a hole in the shell. This small hole produced by the egg tooth on the upper beak of the chick provides atmospheric oxygen for the first time. By this time the lung function is well enough established to allow increased oxygen consumption which is required during the final effort of hatching.
The engineering principles involved in this process are even more remarkable when one considers different kinds of eggs. Not all eggs have the same size pores, but all eggs end up producing the same final concentrations of oxygen and carbon dioxide within the egg. It is rather remarkable when one considers that the incubation of bird eggs ranges all the way from 11 days in some small birds to 70 days for large birds such as the Wandering Albatross. The chemistry involved in a system such as this of moving gases and providing for the embryo inside the egg seems virtually impossible to explain in terms of any kind of evolutionary process. It is another example of God’s wisdom and design in the creation–a design that demands a Designer.
Does God Exist?
718 E. Donmeyer Ave.
South Bend IN 46614-1999
E-mail: jncdge@aol.com
Home page: http://www.doesgodexist.org
718 E. Donmeyer Ave.
South Bend IN 46614-1999
E-mail: jncdge@aol.com
Home page: http://www.doesgodexist.org
Cora Gail Trent
www.cgtrent.com
cgtrent@att.net
