338125
A root elongating at a constant rate exemplifies ____.
1 The simplest expression of geometric growth
2 The simplest expression of arithmetic growth
3 The complex type of geometric growth
4 Parabolic growth without exception
Explanation:
The simplest expression of arithmetic growth is exemplified by a root elongating at a constant rate.
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338126
Sigmoid growth curve has following phases, identify its correct sequence (A) log (B) Stationary (C) Lag
1 \(\mathrm{CBA}\)
2 \(\mathrm{CAB}\)
3 \(\mathrm{BCA}\)
4 \(\mathrm{BAC}\)
Explanation:
In sigmoid growth curve three phases follow the sequence as (1) Lag phase, (2) Log phase, (3) Stationary phase. In most systems, the initial growth is slow (lag phase), and it increases rapidly thereafter - at an exponential rate (log or exponential phase). However, with limited nutrient supply, the growth slows down leading to a stationary phase.
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338127
In arithmetic growth pattern, on plotting the length of the organ against time, ____.
1 A linear curve is obtained.
2 A parabolic curve is obtained
3 A hyperbolic curve is obtained
4 A sigmoid curve is obtained
Explanation:
In arithmetic growth pattern, On plotting the length of the organ against time, a linear curve is obtained. Mathematically, it is expressed as \({{\rm{L}}_{\rm{t}}}{\rm{ = }}{{\rm{L}}_{\rm{0}}}{\rm{ + rt}}\) Where, \({{\rm{L}}_{\rm{t}}}\) = length at time ' \(\mathrm{t}\) ', \({{\rm{L}}_{\rm{0}}}\) = length at time 'zero', \(r\) = growth rate / elongation per unit time
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338148
The progeny cells following mitotic cell division retain the ability to divide and continue to do so, exemplifies ____
1 Linear growth
2 Arithmetic growth
3 Elongational growth
4 Geometric growth
Explanation:
The progeny cells following mitotic cell division retain the ability to divide and continue to do so exemplifies geometrical growth.
338125
A root elongating at a constant rate exemplifies ____.
1 The simplest expression of geometric growth
2 The simplest expression of arithmetic growth
3 The complex type of geometric growth
4 Parabolic growth without exception
Explanation:
The simplest expression of arithmetic growth is exemplified by a root elongating at a constant rate.
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338126
Sigmoid growth curve has following phases, identify its correct sequence (A) log (B) Stationary (C) Lag
1 \(\mathrm{CBA}\)
2 \(\mathrm{CAB}\)
3 \(\mathrm{BCA}\)
4 \(\mathrm{BAC}\)
Explanation:
In sigmoid growth curve three phases follow the sequence as (1) Lag phase, (2) Log phase, (3) Stationary phase. In most systems, the initial growth is slow (lag phase), and it increases rapidly thereafter - at an exponential rate (log or exponential phase). However, with limited nutrient supply, the growth slows down leading to a stationary phase.
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338127
In arithmetic growth pattern, on plotting the length of the organ against time, ____.
1 A linear curve is obtained.
2 A parabolic curve is obtained
3 A hyperbolic curve is obtained
4 A sigmoid curve is obtained
Explanation:
In arithmetic growth pattern, On plotting the length of the organ against time, a linear curve is obtained. Mathematically, it is expressed as \({{\rm{L}}_{\rm{t}}}{\rm{ = }}{{\rm{L}}_{\rm{0}}}{\rm{ + rt}}\) Where, \({{\rm{L}}_{\rm{t}}}\) = length at time ' \(\mathrm{t}\) ', \({{\rm{L}}_{\rm{0}}}\) = length at time 'zero', \(r\) = growth rate / elongation per unit time
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338148
The progeny cells following mitotic cell division retain the ability to divide and continue to do so, exemplifies ____
1 Linear growth
2 Arithmetic growth
3 Elongational growth
4 Geometric growth
Explanation:
The progeny cells following mitotic cell division retain the ability to divide and continue to do so exemplifies geometrical growth.
338125
A root elongating at a constant rate exemplifies ____.
1 The simplest expression of geometric growth
2 The simplest expression of arithmetic growth
3 The complex type of geometric growth
4 Parabolic growth without exception
Explanation:
The simplest expression of arithmetic growth is exemplified by a root elongating at a constant rate.
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338126
Sigmoid growth curve has following phases, identify its correct sequence (A) log (B) Stationary (C) Lag
1 \(\mathrm{CBA}\)
2 \(\mathrm{CAB}\)
3 \(\mathrm{BCA}\)
4 \(\mathrm{BAC}\)
Explanation:
In sigmoid growth curve three phases follow the sequence as (1) Lag phase, (2) Log phase, (3) Stationary phase. In most systems, the initial growth is slow (lag phase), and it increases rapidly thereafter - at an exponential rate (log or exponential phase). However, with limited nutrient supply, the growth slows down leading to a stationary phase.
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338127
In arithmetic growth pattern, on plotting the length of the organ against time, ____.
1 A linear curve is obtained.
2 A parabolic curve is obtained
3 A hyperbolic curve is obtained
4 A sigmoid curve is obtained
Explanation:
In arithmetic growth pattern, On plotting the length of the organ against time, a linear curve is obtained. Mathematically, it is expressed as \({{\rm{L}}_{\rm{t}}}{\rm{ = }}{{\rm{L}}_{\rm{0}}}{\rm{ + rt}}\) Where, \({{\rm{L}}_{\rm{t}}}\) = length at time ' \(\mathrm{t}\) ', \({{\rm{L}}_{\rm{0}}}\) = length at time 'zero', \(r\) = growth rate / elongation per unit time
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338148
The progeny cells following mitotic cell division retain the ability to divide and continue to do so, exemplifies ____
1 Linear growth
2 Arithmetic growth
3 Elongational growth
4 Geometric growth
Explanation:
The progeny cells following mitotic cell division retain the ability to divide and continue to do so exemplifies geometrical growth.
338125
A root elongating at a constant rate exemplifies ____.
1 The simplest expression of geometric growth
2 The simplest expression of arithmetic growth
3 The complex type of geometric growth
4 Parabolic growth without exception
Explanation:
The simplest expression of arithmetic growth is exemplified by a root elongating at a constant rate.
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338126
Sigmoid growth curve has following phases, identify its correct sequence (A) log (B) Stationary (C) Lag
1 \(\mathrm{CBA}\)
2 \(\mathrm{CAB}\)
3 \(\mathrm{BCA}\)
4 \(\mathrm{BAC}\)
Explanation:
In sigmoid growth curve three phases follow the sequence as (1) Lag phase, (2) Log phase, (3) Stationary phase. In most systems, the initial growth is slow (lag phase), and it increases rapidly thereafter - at an exponential rate (log or exponential phase). However, with limited nutrient supply, the growth slows down leading to a stationary phase.
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338127
In arithmetic growth pattern, on plotting the length of the organ against time, ____.
1 A linear curve is obtained.
2 A parabolic curve is obtained
3 A hyperbolic curve is obtained
4 A sigmoid curve is obtained
Explanation:
In arithmetic growth pattern, On plotting the length of the organ against time, a linear curve is obtained. Mathematically, it is expressed as \({{\rm{L}}_{\rm{t}}}{\rm{ = }}{{\rm{L}}_{\rm{0}}}{\rm{ + rt}}\) Where, \({{\rm{L}}_{\rm{t}}}\) = length at time ' \(\mathrm{t}\) ', \({{\rm{L}}_{\rm{0}}}\) = length at time 'zero', \(r\) = growth rate / elongation per unit time
BIOXI15: PLANT GROWTH AND DEVELOPMENT
338148
The progeny cells following mitotic cell division retain the ability to divide and continue to do so, exemplifies ____
1 Linear growth
2 Arithmetic growth
3 Elongational growth
4 Geometric growth
Explanation:
The progeny cells following mitotic cell division retain the ability to divide and continue to do so exemplifies geometrical growth.
