Using a 'Scholander'-type pressure bomb, the effects of climatic or mechani
cal impacts on the water relations of carrots during postharvest handling w
ere investigated to characterise the stresses during the different steps of
the whole chain. Water potential (Psi) provided a valuable means to easily
, rapidly and repeatedly measure a large number of roots during an experime
nt. Water potential of freshly harvested carrots ranged between -0.2 and -0
.6 MPa. Independent of whether the leaves were detached from the roots, Psi
declined by more than 200% (-0.8- -1.5 MPa) during two days of storage at
18 degrees C even if the air humidity was very high ( > 98% RH). While osmo
tic potential (Psi(pi)) was unaffected, pressure potential (Psi(P)) decreas
ed from approximately 0.7 to approximately 0.3 MPa, as determined by pressu
re-volume (PV) analysis or cryoscopy. Storing bunched carrots at moderate a
ir humidity (85% RH) resulted in their water potential falling beyond the t
urgor loss point (i.e. Psi(P) = 0 at Psi approximate to -2.1 MPa in this ex
periment) within 2 days. Repeated falls from a conveyor belt onto either a
steel plate or a belt did not enhance the reduction of Psi in intact, leafl
ess carrots relative to controls during subsequent storage. On the other ha
nd, shaking roots on an oscillation table stress-simulator resulted in a si
gnificant decrease in Psi, reflecting the degree of stress (i.e. time on th
e stress-simulator). In contrast to Psi, changes in water content (from mea
suring dry mass) of randomly selected samples did not clearly indicate the
effects of climatic and mechanical stress on root water relations. (C) 1999
Published by Elsevier Science B.V. All rights reserved.