World News Headlines

Coverage of breaking stories


[Answer] Photosynthetic algae create sugars that will eventually be broken down  during which process?

source : answertrivia.com

[Answer] Photosynthetic algae create sugars that will eventually be broken down during which process?

Answer: glycolysis during respiration

Most relevant text from all around the web:

Photosynthetic algae create sugars that will eventually be broken down during which process?

Photosynthetic algae create sugars that eventually be broken down during : A. Glycolysis during respiration. During this process Algae produced 2 ATP and 2 NADH which is used in forming energy. Explanation: The cleavage down of sugars is called glycolysis. The prefix glyco- means sugar and the suffix -lysis means breaking down.

Photosynthetic algae create sugars that will eventually be broken down during which process ? glycolysis during respiration Which is the site of the most ATP production during cellular respiration?

Photosynthetic algae create sugars that will eventually be broken down during which process? glycolysis during respiration the Calvin cycle during photosynthesis electron transport chain during respiration the Krebs cycle during photosynthesis

glycolysis during respiration Photosynthetic algae create sugars that eventually be broken down during : A. Glycolysis during respiration During this process Algae produced 2 ATP and 2 NADH which is used in forming energy.

glycolysis during respiration Photosynthetic algae create sugars that eventually be broken down during : A. Glycolysis …

Disclaimer: 

Our tool is still learning and trying its best to find the correct answer to your question. Now its your turn, “The more we share The more we have”. Comment any other details to improve the description, we will update answer while you visit us next time…Kindly check our comments section, Sometimes our tool may wrong but not our users.

Are We Wrong To Think We’re Right? Then Give Right Answer Below As Comment

Biology, ATP Flashcards | Quizlet

Biology, ATP Flashcards | Quizlet – Photosynthetic algae create sugars that will eventually be broken down during which process? A) glycolysis, during respiration B) the Calvin cycle, during photosynthesis C) electron transport chain, during respiration D) the Krebs cycle, during photosynthesisPhotosynthetic and Chemosynthetic Organisms: Photoautotrophs, including (a) plants, (b) algae, and (c) cyanobacteria, synthesize their organic compounds via photosynthesis using sunlight as an energy source.Cyanobacteria and planktonic algae can grow over enormous areas in water, at times completely covering the surface.The process of photosynthesis is often described as turning sunlight into sugars, and while that's broadly true, there are two distinct biochemical reactions taking place. The first uses the sunlight to create energy inside the cell and the second takes carbon dioxide and uses it to make sugars.

Overview of Photosynthesis | Boundless Biology – LS1.C: Organization for Matter and Energy Flow in Organisms: Plants, algae (including phytoplankton), and many microorganisms use the energy from light to make sugars (food) from carbon dioxide from the atmosphere and water through the process of photosynthesis, which also releases oxygen. These sugars can be used immediately or stored forCorrect answers: 1 question: Photosynthetic algae create sugars that will eventually be broken down during which process? 1.glycolysis, during respiration 2.the calvin cycle, during photosynthesis 3.electron transport chain, during respiration 4.the krebs cycle, during photosynthesisPhotosynthetic algae create sugars that will eventually be broken down during which process? – 1766432 1. Log in Join now 1. Log in Join now Answer is glycolysis which is a first process in metabolic pathway in this process glucose broken down into two molecule of pyruvic acid. 0.0 0 votes 0 votes Rate! Rate! Thanks. 0.

Overview of Photosynthesis | Boundless Biology

How Is Glucose Made In Photosynthesis | DiabetesTalk.Net – Breaking down photosynthesis stages. Conceptual overview of light dependent reactions. The light-dependent reactions. The Calvin cycle. Photosynthesis evolution. Photosynthesis review. Practice: Photosynthesis. Next lesson. Cellular respiration. Sort by: Top Voted. Photosynthesis.Carbon dioxide is converted to sugar using ATP and NADPH. This process is known as carbon fixation or the Calvin cycle. Carbon dioxide is combined with a 5-carbon sugar creating a 6-carbon sugar….Plants, algae (including phytoplankton), and many microorganisms use the energy from light to make sugars (food) from carbon dioxide from the atmosphere and water through the process of photosynthesis, which also releases oxygen. These sugars can be used immediately or stored for growth or later use. (MS-LS1-6)

Explain the carbon cycle with the help of a diagram - Home ...
Europe - ThinEbook E-books
Europe - ThinEbook E-books
Explain the carbon cycle with the help of a diagram
Europe - ThinEbook E-books
Europe - ThinEbook E-books
Europe - ThinEbook E-books

Photosynthesis – التنفس الخلوي الكربوهيدرات لتنحدث عن واحدة من أهم العمليات الحيوية بصراحة , إذا لم تحدث هذه العملية , من المحتمل أننا لم نكن لنعيش على الأرض , ولم لأكن بصدد وضع هذا الفيديو , لأنه حقا لايوجد مكان لي لأحصل على الطعام والعملية تسمى بـ"البناء الضوئي" وأنتم على الأرجح مطلعون على هذه الفكرة الفكرة ككل هي النبات , و حقيقية البكتيريا والطحالب وأشياء أخرى , لكننا عادة نربطها بالنبات دعوني أجعلها في عبارات جد سهلة , إذن فنحن عادة نربطها بالنبات وهذه العملية تستعملها النباتات , وربما كنا قد تعلمنا هذا عندما كنا صغارا جدا إنها العملية التي تستعملها النباتات لكي تأخذ ثاني أكسيد الكربون بالإضافة إلى بعض الماء و بعض ضوء الشمس وتتحول إلى بعض السكر أو بعض..ربما الكربوهيدرات كربوهيدرات أو سكريات زائد أكسجين من الواضح , أن لديها إثنين من الأجزاء الأساسية لنا ككائنات حية أولا , نحتاج الكربوهيدرات أو السكريات من أجل تزويد أجسامنا لقد رأيتم ذلك في فيدوهات التنفس الخلوي الخاصة بنا بالقيامATPولّــدنا كل ال بالتنفس الخلوي على الغلوكوز , الذي يعتبر بالضرورة كناتج ثانوي أو كربوهيدرات مهدمة إنه الأبسط لنا للقيام بعميلة والثاني كجزء مهم جدا هو الحصول على الأكسجين مرة أخرى , نحتاج إلى استنشاق الأكسجين من أجل هدم الغلوكوز , من أجل التنفس , من أجل القيام بالتنفس الخلوي إذن هذان الشيئان هما مفتاح الحياة , خاصة للحياة التي تستنشق الأكسجين إذن هذه العملية , أكثر من الواقع أنها جالبة للإنتباه , أنه هناك عضويات حولنا , غالبيةً نباتات , التي تعتمد بالفعل على ضوء الشمس عندك هذه التفاعلات المندمجة في الشمس 93 البعيدة بملايين الأميال , وتصدر الفوتونات وبعض الأجزاء الثانوية من هذه الفوتونات تصل إلى سطح الأرض يخترق طريقهم الغيوم و أي شيء آخر وهذه النباتات و البكتيريا و الطحالب يمكنهم إلتقاط الفوتونات وبطريقة ما تحولها إلى سكريات يمكننا بعدها أكلها , وربما البقرة تأكلها ثم نأكل نحن البقرة إذا لم نكن نباتيين , ويمكننا حينها استعمال ذلك لتوليد الطاقة ليس لأن البقرة كلها كربوهيدرات , لكن هذه بالضرورة ما نستعمل كوقود أو كطاقة لكل المركبات الضرورية التي نأكلها هنا أين نحصل على كل وقودنا إذن هذا الوقود للحيوانات.
أو تعلمون , إذا أكلتم حبة بطاطا مباشرة , أنتم مباشرة تحصل على الكربوهيدرات لكن على أي حال , هذا المفهوم البسيط للتركيب الضوئي , لكنه غير صحيح أنا أعني , إذا وجب عليك معرفة شيء وحيد عن التركيب الضوئي هذا قد يكون هو لكن لننقب قليلا بعمق و نحاول الحصول على احشائه ونرى إذا استطعنا أن نفهم أفضل قليلا كيف يحدث هذا فعلا أجده رائعا كيف أن بطريقة ما فوتونات ضوء الشمس تستعمل لصنع جزيئات السكر أو دعونا نتعمق قليلا لنتمكن من كتابة المعادلة الإجمالية للتركيب الضوئي حسنا , لقد كتبتها هنا تقريبا لكن ساكتبها بطريقة علمية محددة قليلا تبدأ أولا ببعض ثاني أكسيد الكربون تضيف إليها بعض الماء , و تضيف إليها ذلك…بدلا من ضوء الشمس , سأقول فوتونات لأن هذه حقا تهيج الإلكترونات في الكلوروفيل الذي يهبط , وممكن أن ترى هذه العملية في هذا الفيديو وسنقوم بكشف المزيد من التفاصيل في فيديوهات قادمة لكن ذاك الإلكترون المتسثار ينتقل إلى مستوى أعلى طاقة , وعندما ينتقل إلى مستوى أقل طاقة , يكون باستطاعتنا التقاط الطاقة لإنتاج جزيئات الطاقة ATP وسنرى NADPHs هذه الجزيئات يستعملون لإنتاج الكربوهيدرات .لكننا سنرى ذلك بعد قليل لكن في الرؤية المجملة للبناء الضوئي , تبدأ بهذه المكونات , وتنتهي بـ كربوهيدرات , والكربوهيدرات يمكن أن يكون جلوكوز لايجب أن يكون جلوكوز دائما والطريقة الإجمالية لكتابة جزئ الكربوهيدرات هي CH2O "عدد طبيعي"=n ويمكن وضع
للحصول على أعداد أكبر يكون على الأقل 3=n من الجزيئات , وعادة ما يكون 6 في حالة الغلوكوز , لديك 6 كربون , 12 هيدروجين و 6 أكسجين . إذن هذه الصيغة العامة للكربوهيدرات , لكن يمكنك الحصول على أضعاف ذلك. يمكنك الحصول أيضا على هذه السلاسل الطويلة من الكربوهيدرات , إذن يمكنك الحصول على كربوهيدرات "نشاء" وبعدها الحصول على بعض الأكسجين هذه هنا ليست مختلفة كثيرا من التي كتبتها هنا في التظرة الأولى حول كيفية أن نتخيل البناء الضوئي في ذهننا لجعل هذه المعادلة متوازنة …لنرى , لدي n من الكربون إذن أحتاج إلى كربون هناك لنرى، لدي 2n من الهيدروجين هنا هناك 2n من الهيدروجين وعندي n إذن احتاج الى 2n من الهيدروجين هنا حسنا، ساضع n هناك لنرى كم من جزيئات الأكسجين يوجد لدي 2n أكسجين، وواحدة اخرى إذن لدي 3n من جزيئات الأكسجين إذن لنرى , عندي واحدة n، وانت وضعت n هنا فبذلك يكون لدي 2n، وانا ار بذلك ان المعادلة اتزنت فهذه 30 الف مرة تكبير مما يحدث فعلا في عملية البناء الضوئي ولكن عندما تتعمق اكثر، سوف ترى أن هذا لا يحدث مباشرة، أن هذا يحدث من خلال عمليات جانبية التي تنتهي بصنع الكربوهيدرات بصورة عامة، نحن نستطيع أن نقوم بتكسير البناء الضوئي. سوف اكتب هذه الجملة هنا. نستطيع ان نقوم بتكسير عملية البناء الضوئي وسوف نتعمق اكثر في فيديوهات قادمة، ولكن اريد أن أحصل على نظرة شاملة، من خلال خطوتين. .

Intro to Photosynthesis – Part 1 – .

Intro to vascular tissues (xylem & phloem) | Life processes | Biology | Khan Academy – – [Instructor] When
plants appear on the land for the very first time, these plants were extremely tiny like moss and algae.
And for a few million years, there were no plants on our planet, which could grow taller than few inches. But why? Well, turns out growing
tall has some challenges. However, with time, plants
slowly started evolving and eventually they were able
to overcome those challenges. And as you know, today
we can have tall plants, plants which can grow into trees, trees which can grow
hundreds of meters tall. And so the question we wanna
try and answer in this video is what are the challenges
that the early plants faced because of which they couldn't grow tall? And how did they overcome them? So, the biggest challenge
that these early plants faced was a lack of a transport system. What's a transport system
and why do they need them? Well, let's take an example
and understand this. For example, consider my house plant. In order for this plant to stay alive, all the parts of it require
food and water and minerals so that they can grow. But where are they available? Now you might know that most of the water and the minerals are
available in the soil. So the soil contains water,
and it has minerals in it. Minerals. And the plants have roots which can absorb these water
and minerals, so great. But what about the rest
of the part of the plants? Like the leaves, how
do they get that water? Well, and you see, the
plants need to transport that water from the roots
all the way to the leaves and all the other parts. So can you see that a
transport system is needed to transport this water and
its dissolved minerals up? Right? Similarly, think about food. How do plants get their food? You might know that they photosynthesize. They use the energy of the
sun to create their own food. And most of these photosynthesis
happens in the leaves. So let's say some of the food is synthesized in these leaves. Consider these are food. These are basically sugars. Let's just call them as food as of now. Now, what about the parts of the plant that cannot photosynthesize? For example, roots can't photosynthesize because they're under the ground, they're not exposed to sunlight. There maybe certain
growing parts of the plant which might require this food because they cannot photosynthesize. Maybe there are some leaves somewhere which are in absolute
shade and because of it, they're not able to photosynthesize. So again, what to do? We need a transport system. The food needs to get transported
to the different parts. So again, the food need
to get transported down maybe to the roots sometimes. It might have to get transported
up to some other parts. So can you see, a transport
system is necessary. Without which, these
plants cannot survive. And the earlier plants didn't
have a transport system. And therefore, they are very tiny. The thing is, if you are very tiny, then, this transportation
happens just by diffusion. Diffusion is a process
in which stuff moves from a region of high concentration
to lower concentration. So, if it's very tiny,
these food particles, these sugars can easily move into the different parts of the plant. They can easily diffuse into it. Similarly, the water can
easily diffuse to all the different parts of the plant. But as the plants get taller, then, diffusion becomes super
slow and it almost becomes impossible to transport
it just by diffusion. This is where specialized
transport system is needed. And so, eventually, plants
evolved this transport system. Today, they are called
as vascular tissues. So the transport system evolved
are called vascular tissues. And the word vascular,
vascular means vessels. I like to think of them as pipes, so you can think of them as pipes. So piping system through
which they can move the food and water all around their body. And what do these vascular
tissues look like? Well, just like the name
suggests, they look like pipes. So pipes which start from the roots. So let me show you the roots. And so, pipes that start from the roots and go all the way to
each and every leaves. I'm not showing it for all the leaves, but it goes to each and every leaves. But wait, you maybe thinking, how can we use one pipe to
transport both food and water? Wouldn't they get mixed up? Well, to make sure they
don't get mixed up, we have two separate piping systems. So one for water and one for food. And we give them names. So the piping system that we
use for water is called xylem. So xylem transports water. And the dissolved minerals. When we say water, it already
has dissolved minerals. And for food, we have
another tissue called phloem. And this one transports
food, mostly sugars, but it can also transport
other things like hormones, amino acids and other
stuff, but mostly food. And the way I like to remember this, I remember watching this
in some YouTube video, I like to remember this as fo for food and pho for phloem, so
food, phloem, fo pho. And another reason why
they have to be separate is because if you look at water, the water transport is
only one direction, up. Can you see why? Because all the water and
minerals are present in the roots. So, we just have to
transport up to all leaves. But the food transport has
to be in both directions. Sometimes, you would
want the food to go up, maybe to the growing areas of the plants, sometimes, you want the food
to go down in the roots, that's where the storing organs are. So, you see food needs to be
transported in both directions and therefore, xylem is
only one way transport up and phloem, well that
is a two-way transport. So it makes perfect sense
to have two separate vascular tissues altogether. And so this one line I have drawn, don't think of this as single
pipe but imagine it's a bundle of a lot of xylem pipes and a
lot of phloem pipes together. In fact, let me show you a little better. If I were to zoom in onto this, and if we could see
inside, these are the xylem and the phloem bundles. Again, each one has a lot of xylem and phloem tissues inside. And if you could see from the top, if you could have a
microscopic view of this, then, it would look somewhat like this. This is what you would
see in a microscope. And what you're seeing over here, these are the vascular tissues. Again, let me zoom in even further. So if we zoom in one of
these parts, you can see a lot of round things over here. These are the xylem,
let me just mark them. These round things that
you're seeing over here, these are the xylem tissues. They are the pipes that are
coming out of the screen. Think of it that way. They're the one that transport water. These over here. And then, you can see
pipes over here as well. You can see small, small round
things over here as well, they are much thinner than
xylem, these are the phloem. In between, you have other cells. But these are the phloem. And so, you can see a lot
of xylem and a lot of phloem are bundled together,
along with some other supporting cells as well. And that bundle is what
I've drawn over here. So the single thing that
I've drawn over here is both lots of xylems and
lots of phloem together. And these pipes, they start from the roots and they end all the way into the leaves. So, let me show you a zoomed
in version of the leaf. You may have seen a leaf like this. The veins that you see in
the leaves are actually the xylem and the phloem. These are the vascular tissues. And then you can see they branch off, into becoming smaller and smaller, let me zoom in even further. And you can see them branching
off like a network of roads connecting different
different parts of the city. This way, they make sure
a maximum number of cells are able to get the food and water. That's how the transport
system in plants work. Isn't that amazing? And now that they have the
developed the vascular tissues, nothing can stop them from growing tall, growing into trees, to grow
hundreds of meters tall. Because of which, we have forests and jungles and everything. But finally, you might
have another question. How do these transport systems even work? I mean in tall trees, how are
they able to get that water from the ground all the way to the top? Is there some kind of a pump? And I guess that's where things
get even more interesting. No, they don't have a pump. Yet, they use some clever
mechanism to get their job done. And we look at these
mechanisms in great detail in the future videos, okay? But one of the things
about not having a pump is that this whole
system becomes very slow. So plants, because they don't have a pump, they have slow transport system. But you know what? That's fine for them. The plants are saying, it's
okay, we don't have a rush. We don't have to go anywhere. They have pretty low energy demands so they can easily survive with a very slow transport system. They don't need a pump. Unlike animals who have
very high energy demands and animals do need a pump,
that's why we have a heart, heart is our pump. But plants and trees,
they don't need that. And as I said, we will look
at how these things work without a pump in the future videos. Anyways, that's it for this video. So let's quickly summarize. What did we learn in the video? We saw that plants have
developed a piping system to transport food and water which we call the vascular tissues. We have two different ones. One to transport water, unidirectional transport called xylem. And one to transport
food in both directions, bidirectional of called phloem. And the way I like to remember this is fo for food, pho for phloem. And since they don't have a
heart, their transport system is pretty slow, but that's fine because their energy
demands are pretty low. As they don't have to go anywhere, they're pretty much still. And I would like to end by asking you to wonder about one thing. Can you imagine about how
different our world would be without vascular tissues? .